aboutsummaryrefslogblamecommitdiffstats
path: root/erts/emulator/beam/beam_load.c
blob: df5602b0402cbdf5f7797d4b45445d702e9652f4 (plain) (tree)
1
2
3
4
5
6
7
8
9
10
2404
2405
2406
2407
2408
2409
2410
2411
2412
2413
2414
2415
2416
2417
2418
2419
2420
2421
2422
2423
2424
2425
2426
2427
2428
2429
2430
2431
2432
2433
2434
2435
2436
2437
2438
2439
2440
2441
2442
2443
2444
2445
2446
2447
2448
2449
2450
2451
2452
2453
2454
2455
2456
2457
2458
2459
2460
2461
2462
2463
2464
2465
2466
2467
2468
2469
2470
2471
2472
2473
2474
2475
2476
2477
2478
2479
2480
2481
2482
2483
2484
2485
2486
2487
2488
2489
2490
2491
2492
2493
2494
2495
2496
2497
2498
2499
2500
2501
2502
2503
2504
2505
2506
2507
2508
2509
2510
2511
2512
2513
2514
2515
2516
2517
2518
2519
2520
2521
2522
2523
2524
2525
2526
2527
2528
2529
2530
2531
2532
2533
2534
2535
2536
2537
2538
2539
2540
2541
2542
2543
2544
2545
2546
2547
2548
2549
2550
2551
2552
2553
2554
2555
2556
2557
2558
2559
2560
2561
2562
2563
2564
2565
2566
2567
2568
2569
2570
2571
2572
2573
2574
2575
2576
2577
2578
2579
2580
2581
2582
2583
2584
2585
2586
2587
2588
2589
2590
2591
2592
2593
2594
2595
2596
2597
2598
2599
2600
2601
2602
2603
2604
2605
2606
2607
2608
2609
2610
2611
2612
2613
2614
2615
2616
2617
2618
2619
2620
2621
2622
2623
2624
2625
2626
2627
2628
2629
2630
2631
2632
2633
2634
2635
2636
2637
2638
2639
2640
2641
2642
2643
2644
2645
2646
2647
2648
2649
2650
2651
2652
2653
2654
2655
2656
2657
2658
2659
2660
2661
2662
2663
2664
2665
2666
2667
2668
2669
2670
2671
2672
2673
2674
2675
2676
2677
2678
2679
2680
2681
2682
2683
2684
2685
2686
2687
2688
2689
2690
2691
2692
2693
2694
2695
2696
2697
2698
2699
2700
2701
2702
2703
2704
2705
2706
2707
2708
2709
2710
2711
2712
2713
2714
2715
2716
2717
2718
2719
2720
2721
2722
2723
2724
2725
2726
2727
2728
2729
2730
2731
2732
2733
2734
2735
2736
2737
2738
2739
2740
2741
2742
2743
2744
2745
2746
2747
2748
2749
2750
2751
2752
2753
2754
2755
2756
2757
2758
2759
2760
2761
2762
2763
2764
2765
2766
2767
2768
2769
2770
2771
2772
2773
2774
2775
2776
2777
2778
2779
2780
2781
2782
2783
2784
2785
2786
2787
2788
2789
2790
2791
2792
2793
2794
2795
2796
2797
2798
2799
2800
2801
2802
2803
2804
2805
2806
2807
2808
2809
2810
2811
2812
2813
2814
2815
2816
2817
2818
2819
2820
2821
2822
2823
2824
2825
2826
2827
2828
2829
2830
2831
2832
2833
2834
2835
2836
2837
2838
2839
2840
2841
2842
2843
2844
2845
2846
2847
2848
2849
2850
2851
2852
2853
2854
2855
2856
2857
2858
2859
2860
2861
2862
2863
2864
2865
2866
2867
2940
2941
2942
2943
2944
2945
2946
2947
2948
2949
2950
2951
2952
2953
2954
2955
2956
2957
2958
2959
2960
2961
2962
2963
2964
2965
2966
2967
2968
2969
2970
2971
2972
2973
2974
2975
2976
2977
2978
2979
2980
2981
2982
2983
2984
2985
2986
2987
2988
2989
2990
2991
2992
2993
2994
2995
2996
2997
2998
2999
3000
3001
3002
3003
3004
3005
3006
3007
3008
3009
3010
3011
3012
3013
3014
3015
3016
3017
3018
3019
3020
3021
3022
3023
3024
3025
3026
3027
3028
3029
3030
3031
3032
3033
3034
3035
3036
3037
3038
3039
3040
3041
3042
3043
3044
3045
3046
3047
3048
3049
3050
3051
3052
3053
3054
3055
3056
3057
3058
3059
3060
3061
3062
3063
3064
3065
3066
3067
3068
3069
3070
3071
3072
3073
3074
3075
3076
3077
3078
3079
3080
3081
3082
3083
3084
3085
3086
3087
3088
3089
3090
3091
3092
3093
3094
3095
3096
3097
3098
3099
3100
3101
3102
3103
3104
3105
3106
3107
3108
3109
3110
3111
3112
3113
3114
3115
3116
3117
3118
3119
3120
3121
3122
3123
3124
3125
3126
3127
3128
3129
3130
3131
3132
3133
3134
3135
3136
3137
3138
3139
3140
3141
3142
3143
3144
3145
3146
3147
3148
3149
3150
3151
3152
3153
3154
3155
3156
3157
3158
3159
3160
3161
3162
3163
3164
3165
3166
3167
3168
3169
3170
3171
3172
3173
3174
3175
3176
3177
3178
3179
3180
3181
3182
3183
3184
3185
3186
3187
3188
3189
3190
3191
3192
3193
3194
3195
3196
3197
3198
3199
3200
3201
3202
3203
3204
3205
3206
3207
3208
3209
3210
3211
3212
3213
3214
3215
3216
3217
3218
3219
3220
3221
3222
3223
3224
3225
3226
3227
3228
3229
3230
3231
3232
3233
3234
3235
3236
3237
3238
3239
3240
3241
3242
3243
3244
3245
3246
3247
3248
3249
3250
3251
3252
3253
3254
3255
3256
3257
3258
3259
3260
3261
3262
3263
3264
3265
3266
3267
3268
3269
3270
3271
3272
3273
3274
3275
3276
3277
3278
3279
3280
3281
3282
3283
3284
3285
3286
3287
3288
3289
3290
3291
3292
3293
3294
3295
3296
3297
3298
3299
3300
3301
3302
3303
3304
3305
3306
3307
3308
3309
3310
3311
3312
3313
3314
3315
3316
3317
3318
3319
3320
3321
3322
3323
3324
3325
3326
3327
3328
3329
3330
3331
3332
3333
3334
3335
3336
3337
3338
3339
3340
3341
3342
3343
3344
3345
3346
3347
3348
3349
3350
3351
3352
3353
3354

                   


                                                        




                                                                      
  



                                                                         
  




































                                                
                                          
     
                                                  







































                                                                                      
                                                               














































                                                                             
                                                                  


































































































































                                                                                       
                                                  

                                                                     
                                                                                              
                                                                                          
                                                                           



























































                                                                                        
                      













































                                                              
                                











































































                                                                                     
                                                                          




















                                                                           








                                                                        

                                                                                  











                                                                       
                                                   












































































                                                                                        
                                     
 

                                                                                 







                                                                               















                                                                         

                                                     



                                       










                                                                              
                                       








                                                         
                                       








                                                  
                                       








                                                   
                                       










                                                                
                                       










                                                                             
                                       


                                      
                             

                        




                                       





                                                                    
                                       









                                                                     
                                       




                                                                            
                                       




                        
                                       





                                                     


























































































                                                                                  
                                                                                                








































                                                                            
                                                           
























































































































































































































































                                                                                       
                                                         


































































                                                                                                                            
                                                         



































































                                                                                              
                              




















































































































                                                                                 

                                                                               




                                                     
                                

                                        
                                   


                                           













                                                                      




                                                                         
                                                                                 
                                                                         
                                                                                 

                                                                         
    
                                                                                                              











                                                                         
                    

























































                                                                       
                         







                                                                  
                            







                                                     
                                

























































                                                                                   
                                      






                                                           

                                                           





                                                                                 
                                      



































                                                                                       



                                                



























                                                                                 
                                          





























































































































                                                                                    
                                                                                




































                                                                
                                                                                   




























                                                                      
                                                                                  




























































































                                                                                         
                                                           
                      
                                                            

                                           
                                                                                  






















                                                                   
                            




                                                            
                            


                                                
                            










                                                                   
                                   
                                  
                                       

                                            






                                                               
                         
                                  
                                               

                                      
                                                                                          











                                                                                   



                                                                                   
                                    


















                                                                            



                                                                                











                                                                       
                                                                       



































                                                                                                   
                                      

                                                                                                      









                                                             
 





















                                                                                    




























































                                                                                         


















































































































































































































                                                                              
               















































































































































































































































































































































































































































































                                                                               
                                      





                               
                                      









                                                  

                                         
                                         


            
                                      





















                                                                          
                                      





                               
                                      









                                                  

                                         
                                         


            
                                      






























































































































































































































































































































































































































                                                                                        
                                  




                                                  






                                                                           
             
                                                                            










                                         

                                                                          
                         
                                                             
                              
                                                           
                                  
                                                               
                                   
                                                                
                             
                                                          
                               
                                                            
                               
                                                            
                               
                                                            









                    






































































                                                                               








                                                               
                                
                             























                                                                 
                                                                                      





                                               
                                                                            
                                 




                                                                
                                                                             
                                 





                                                 
                                                                          


                                          
                                 
 
                                          

                                                                    
                                     

       


                   

                         
                                      
                                             

                                                  






























                                                                 
                              











                                                           
                                               




                                                                                  
                                 
 


                                                                       


                                                                                      

                                                                      





                                                                                     
                                 

                                                                 
                                 

                                                                  
                                 
                                                        
                                 
                                                                            
                                 
                                                                           
                                 


                                                                                           
                                 

                                                     
                                 
 









                                                                               
                                                                

                     
                                 




                                              
                              



                                         
                                         


                          
                                 


















                                                        
                                                          


                                    
                                 






                                     
                                     
                                              
                                                                         



                                            
                                 







                                                   
                                 
































                                                                          
                                                             










                                              
                         





                                       
                                                               
















                                                         
                                                                                             


































































































































                                                                              
                                                                                      






































































































































































































































































                                                                                   
                                                               






























                                                                            
                                                                      



















                                               
                       

                              
                                           
                                   
                             






















































































































































































































































                                                                                
                    
















                                             
                                                                  

                                          





















                                                             
                    





















                                                
                                                                  

                                          








































                                                                                
                                                                   































                                                                              
                    






































                                                                          
                    






























                                                                          

                                    










                                           


                                                                          















































































































                                                                                   

                                                                                          
 
                                                    

















                                                                        

                                                                               




                                                     
                                     









































                                                                                   
                                                 

























































































































































































                                                                                   

                        
              


                           























































































                                                                              
                                                                                  












                                                      
                           

                                   
                              

                                      
                                      

















































                                                                           
                                 











                                                                                 

                                                

































































                                                                             
                                                  
 
                                                                                                     







                              
/*
 * %CopyrightBegin%
 *
 * Copyright Ericsson AB 1996-2010. All Rights Reserved.
 *
 * The contents of this file are subject to the Erlang Public License,
 * Version 1.1, (the "License"); you may not use this file except in
 * compliance with the License. You should have received a copy of the
 * Erlang Public License along with this software. If not, it can be
 * retrieved online at http://www.erlang.org/.
 *
 * Software distributed under the License is distributed on an "AS IS"
 * basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
 * the License for the specific language governing rights and limitations
 * under the License.
 *
 * %CopyrightEnd%
 */

#ifdef HAVE_CONFIG_H
#  include "config.h"
#endif

#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_version.h"
#include "erl_process.h"
#include "error.h"
#include "erl_driver.h"
#include "bif.h"
#include "external.h"
#include "beam_load.h"
#include "big.h"
#include "erl_bits.h"
#include "beam_catches.h"
#include "erl_binary.h"
#include "erl_zlib.h"

#ifdef HIPE
#include "hipe_bif0.h"
#include "hipe_mode_switch.h"
#include "hipe_arch.h"
#endif

ErlDrvBinary* erts_gzinflate_buffer(char*, int);

#define MAX_OPARGS 8
#define CALLED    0
#define DEFINED   1
#define EXPORTED  2

#ifdef NO_JUMP_TABLE
#  define BeamOpCode(Op) ((BeamInstr)(Op))
#else
#  define BeamOpCode(Op) ((BeamInstr)beam_ops[Op])
#endif

#if defined(WORDS_BIGENDIAN)
# define NATIVE_ENDIAN(F)			\
  if ((F).val & BSF_NATIVE) {			\
     (F).val &= ~(BSF_LITTLE|BSF_NATIVE);	\
  } else {}
#else
# define NATIVE_ENDIAN(F)			\
  if ((F).val & BSF_NATIVE) {			\
      (F).val &= ~BSF_NATIVE;			\
      (F).val |= BSF_LITTLE;			\
  } else {}
#endif

/*
 * Errors returned from tranform_engine().
 */
#define TE_OK 0
#define TE_FAIL (-1)
#define TE_SHORT_WINDOW (-2)

typedef struct {
    Uint value;			/* Value of label (NULL if not known yet). */
    Uint patches;		/* Index (into code buffer) to first location
				 * which must be patched with the value of this label.
				 */
#ifdef ERTS_SMP
    Uint looprec_targeted;	/* Non-zero if this label is the target of a loop_rec
				 * instruction.
				 */
#endif
} Label;

/*
 * Type for a operand for a generic instruction.
 */

typedef struct {
    unsigned type;		/* Type of operand. */
    BeamInstr val;			/* Value of operand. */
    Uint bigarity;		/* Arity for bignumbers (only). */
} GenOpArg;

/*
 * A generic operation.
 */

typedef struct genop {
    int op;			/* Opcode. */
    int arity;			/* Number of arguments. */
    GenOpArg def_args[MAX_OPARGS]; /* Default buffer for arguments. */
    GenOpArg* a;		/* The arguments. */
    struct genop* next;		/* Next genop. */
} GenOp;

/*
 * The allocation unit for generic blocks.
 */
  
typedef struct genop_block {
    GenOp genop[32];
    struct genop_block* next;
} GenOpBlock;

/*
 * This structure contains information for an imported function or BIF.
 */
typedef struct {
    Eterm module;		/* Tagged atom for module. */
    Eterm function;		/* Tagged atom for function. */
    int arity;			/* Arity. */
    Uint patches;		/* Index to locations in code to
				 * eventually patch with a pointer into
				 * the export entry.
				 */
    BifFunction bf;		/* Pointer to BIF function if BIF;
				 * NULL otherwise.
				 */
} ImportEntry;

/*
 * This structure contains information for a function exported from a module.
 */

typedef struct {
    Eterm function;		/* Tagged atom for function. */
    int arity;			/* Arity. */
    BeamInstr* address;		/* Address to function in code. */
} ExportEntry;

#define MakeIffId(a, b, c, d) \
  (((Uint) (a) << 24) | ((Uint) (b) << 16) | ((Uint) (c) << 8) | (Uint) (d))

#define ATOM_CHUNK 0
#define CODE_CHUNK 1
#define STR_CHUNK 2
#define IMP_CHUNK 3
#define EXP_CHUNK 4
#define NUM_MANDATORY 5

#define LAMBDA_CHUNK 5
#define LITERAL_CHUNK 6
#define ATTR_CHUNK 7
#define COMPILE_CHUNK 8

#define NUM_CHUNK_TYPES (sizeof(chunk_types)/sizeof(chunk_types[0]))

/*
 * An array with all chunk types recognized by the loader.
 */

static Uint chunk_types[] = {
    /*
     * Mandatory chunk types -- these MUST be present.
     */
    MakeIffId('A', 't', 'o', 'm'), /* 0 */
    MakeIffId('C', 'o', 'd', 'e'), /* 1 */
    MakeIffId('S', 't', 'r', 'T'), /* 2 */
    MakeIffId('I', 'm', 'p', 'T'), /* 3 */
    MakeIffId('E', 'x', 'p', 'T'), /* 4 */

    /*
     * Optional chunk types -- the loader will use them if present.
     */
    MakeIffId('F', 'u', 'n', 'T'), /* 5 */
    MakeIffId('L', 'i', 't', 'T'), /* 6 */
    MakeIffId('A', 't', 't', 'r'), /* 7 */
    MakeIffId('C', 'I', 'n', 'f'), /* 8 */
};

/*
 * This structure keeps load-time information about a lambda.
 */

typedef struct {
    ErlFunEntry* fe;		/* Entry in fun table. */
    unsigned label;		/* Label of function entry. */
    Uint32 num_free;		/* Number of free variables. */
    Eterm function;		/* Name of local function. */
    int arity;			/* Arity (including free variables). */
} Lambda;

/*
 * This structure keeps load-time information about a literal.
 */

typedef struct {
    Eterm term;			/* The tagged term (in the heap). */
    Uint heap_size;		/* (Exact) size on the heap. */
    Uint offset;		/* Offset from temporary location to final. */
    Eterm* heap;		/* Heap for term. */
} Literal;

/*
 * This structure keeps information about an operand that needs to be
 * patched to contain the correct address of a literal when the code is
 * frozen.
 */

typedef struct literal_patch LiteralPatch;
struct literal_patch {
    int pos;			/* Position in code */
    LiteralPatch* next;
};

/*
 * This structure keeps information about an operand that needs to be
 * patched to contain the correct address for an address into the string table.
 */

typedef struct string_patch StringPatch;
struct string_patch {
    int pos;			/* Position in code */
    StringPatch* next;
};

/*
 * This structure contains all information about the module being loaded.
 */  

typedef struct {
    /*
     * The current logical file within the binary.
     */

    char* file_name;		/* Name of file we are reading (usually chunk name). */
    byte* file_p;		/* Current pointer within file. */
    unsigned file_left;		/* Number of bytes left in file. */

    /*
     * The following are used mainly for diagnostics.
     */

    Eterm group_leader;		/* Group leader (for diagnostics). */
    Eterm module;		/* Tagged atom for module name. */
    Eterm function;		/* Tagged atom for current function
				 * (or 0 if none).
				 */
    unsigned arity;		/* Arity for current function. */

    /*
     * All found chunks.
     */

    struct {
	byte* start;		/* Start of chunk (in binary). */
	unsigned size;		/* Size of chunk. */
    } chunks[NUM_CHUNK_TYPES];

    /*
     * Used for code loading (mainly).
     */

    byte* code_start;		/* Start of code file. */
    unsigned code_size;		/* Size of code file. */
    int specific_op;		/* Specific opcode (-1 if not found). */
    int num_functions;		/* Number of functions in module. */
    int num_labels;		/* Number of labels. */
    int code_buffer_size;	/* Size of code buffer in words.  */
    BeamInstr* code;		/* Loaded code. */
    int ci;			/* Current index into loaded code. */
    Label* labels;
    BeamInstr new_bs_put_strings;	/* Linked list of i_new_bs_put_string instructions. */
    StringPatch* string_patches; /* Linked list of position into string table to patch. */
    BeamInstr catches;		/* Linked list of catch_yf instructions. */
    unsigned loaded_size;	/* Final size of code when loaded. */
    byte mod_md5[16];		/* MD5 for module code. */
    int may_load_nif;           /* true if NIFs may later be loaded for this module */  
    int on_load;		/* Index in the code for the on_load function
				 * (or 0 if there is no on_load function)
				 */

    /*
     * Atom table.
     */

    int num_atoms;		/* Number of atoms in atom table. */
    Eterm* atom;		/* Atom table. */

    int num_exps;		/* Number of exports. */
    ExportEntry* export;	/* Pointer to export table. */

    int num_imports;		/* Number of imports. */
    ImportEntry* import;	/* Import entry (translated information). */

    /*
     * Generic instructions.
     */
    GenOp* genop;		/* The last generic instruction seen. */
    GenOp* free_genop;		/* List of free genops. */
    GenOpBlock* genop_blocks;	/* List of all block of allocated genops. */

    /*
     * Lambda table.
     */

    int num_lambdas;		/* Number of lambdas in table. */
    int lambdas_allocated;	/* Size of allocated lambda table. */
    Lambda* lambdas;		/* Pointer to lambdas. */
    Lambda def_lambdas[16];	/* Default storage for lambda table. */
    char* lambda_error;		/* Delayed missing 'FunT' error. */

    /*
     * Literals (constant pool).
     */

    int num_literals;		/* Number of literals in table. */
    int allocated_literals;	/* Number of literal entries allocated. */
    Literal* literals;		/* Array of literals. */
    LiteralPatch* literal_patches; /* Operands that need to be patched. */
    Uint total_literal_size;	/* Total heap size for all literals. */

    /*
     * Floating point.
     */
    int new_float_instructions;	/* New allocation scheme for floating point. */
} LoaderState;

typedef struct {
    unsigned num_functions;	/* Number of functions. */
    Eterm* func_tab[1];		/* Pointers to each function. */
} LoadedCode;

#define GetTagAndValue(Stp, Tag, Val) \
   do { \
      BeamInstr __w; \
      GetByte(Stp, __w); \
      Tag = __w & 0x07; \
      if ((__w & 0x08) == 0) { \
	 Val = __w >> 4; \
      } else if ((__w & 0x10) == 0) { \
	 Val = ((__w >> 5) << 8); \
	 GetByte(Stp, __w); \
	 Val |= __w; \
      } else { \
	if (!get_int_val(Stp, __w, &(Val))) goto load_error; \
      } \
   } while (0)


#define LoadError0(Stp, Fmt) \
    do { \
	load_printf(__LINE__, Stp, Fmt); \
	goto load_error; \
    } while (0)

#define LoadError1(Stp, Fmt, Arg1) \
    do { \
	load_printf(__LINE__, stp, Fmt, Arg1); \
	goto load_error; \
    } while (0)

#define LoadError2(Stp, Fmt, Arg1, Arg2) \
    do { \
	load_printf(__LINE__, Stp, Fmt, Arg1, Arg2); \
	goto load_error; \
    } while (0)

#define LoadError3(Stp, Fmt, Arg1, Arg2, Arg3) \
    do { \
	load_printf(__LINE__, stp, Fmt, Arg1, Arg2, Arg3); \
	goto load_error; \
    } while (0)

#define EndOfFile(Stp) (stp->file_left == 0)

#define GetInt(Stp, N, Dest) \
    if (Stp->file_left < (N)) { \
       short_file(__LINE__, Stp, (N)); \
       goto load_error; \
    } else { \
       int __n = (N); \
       BeamInstr __result = 0; \
       Stp->file_left -= (unsigned) __n; \
       while (__n-- > 0) { \
          __result = __result << 8 | *Stp->file_p++; \
       } \
       Dest = __result; \
    } while (0)

#define GetByte(Stp, Dest) \
    if ((Stp)->file_left < 1) { \
       short_file(__LINE__, (Stp), 1); \
       goto load_error; \
    } else { \
       Dest = *(Stp)->file_p++; \
       (Stp)->file_left--; \
    }

#define GetString(Stp, Dest, N) \
    if (Stp->file_left < (N)) { \
       short_file(__LINE__, Stp, (N)); \
       goto load_error; \
    } else { \
       Dest = (Stp)->file_p; \
       (Stp)->file_p += (N); \
       (Stp)->file_left -= (N); \
    }

#define GetAtom(Stp, Index, Dest) \
    if ((Index) == 0) { \
       LoadError1((Stp), "bad atom index 0 ([]) in %s", stp->file_name); \
    } else if ((Index) < (Stp)->num_atoms) { \
       Dest = (Stp)->atom[(Index)]; \
    } else { \
       LoadError2((Stp), "bad atom index %d in %s", (Index), stp->file_name); \
    }

#ifdef DEBUG
# define GARBAGE 0xCC
# define DEBUG_INIT_GENOP(Dst) memset(Dst, GARBAGE, sizeof(GenOp))
#else
# define DEBUG_INIT_GENOP(Dst)
#endif

#define NEW_GENOP(Stp, Dst) \
  do { \
    if ((Stp)->free_genop == NULL) { \
       new_genop((Stp)); \
    } \
   Dst = (Stp)->free_genop; \
   (Stp)->free_genop = (Stp)->free_genop->next; \
   DEBUG_INIT_GENOP(Dst); \
   (Dst)->a = (Dst)->def_args; \
  } while (0)

#define FREE_GENOP(Stp, Genop) \
 do { \
   if ((Genop)->a != (Genop)->def_args) { \
       erts_free(ERTS_ALC_T_LOADER_TMP, (Genop)->a); \
   } \
   (Genop)->next = (Stp)->free_genop; \
   (Stp)->free_genop = (Genop); \
 } while (0)

#define GENOP_ARITY(Genop, Arity) \
  do { \
   ASSERT((Genop)->a == (Genop)->def_args); \
   (Genop)->arity = (Arity); \
   (Genop)->a = erts_alloc(ERTS_ALC_T_LOADER_TMP, \
			   (Genop)->arity * sizeof(GenOpArg)); \
  } while (0)


static int bin_load(Process *c_p, ErtsProcLocks c_p_locks,
		    Eterm group_leader, Eterm* modp, byte* bytes, int unloaded_size);
static void init_state(LoaderState* stp);
static int insert_new_code(Process *c_p, ErtsProcLocks c_p_locks,
			   Eterm group_leader, Eterm module,
			   BeamInstr* code, Uint size, BeamInstr catches);
static int scan_iff_file(LoaderState* stp, Uint* chunk_types,
			 Uint num_types, Uint num_mandatory);
static int load_atom_table(LoaderState* stp);
static int load_import_table(LoaderState* stp);
static int read_export_table(LoaderState* stp);
static int read_lambda_table(LoaderState* stp);
static int read_literal_table(LoaderState* stp);
static int read_code_header(LoaderState* stp);
static int load_code(LoaderState* stp);
static GenOp* gen_element(LoaderState* stp, GenOpArg Fail, GenOpArg Index,
			  GenOpArg Tuple, GenOpArg Dst);
static GenOp* gen_split_values(LoaderState* stp, GenOpArg S, GenOpArg Fail,
			       GenOpArg Size, GenOpArg* Rest);
static GenOp* gen_select_val(LoaderState* stp, GenOpArg S, GenOpArg Fail,
			     GenOpArg Size, GenOpArg* Rest);
static GenOp* gen_select_big(LoaderState* stp, GenOpArg S, GenOpArg Fail,
			     GenOpArg Size, GenOpArg* Rest);
static GenOp* const_select_val(LoaderState* stp, GenOpArg S, GenOpArg Fail,
			       GenOpArg Size, GenOpArg* Rest);
static GenOp* gen_func_info(LoaderState* stp, GenOpArg mod, GenOpArg Func,
			    GenOpArg arity, GenOpArg label);

static int freeze_code(LoaderState* stp);

static void final_touch(LoaderState* stp);
static void short_file(int line, LoaderState* stp, unsigned needed);
static void load_printf(int line, LoaderState* context, char *fmt, ...);
static int transform_engine(LoaderState* st);
static void id_to_string(Uint id, char* s);
static void new_genop(LoaderState* stp);
static int get_int_val(LoaderState* stp, Uint len_code, BeamInstr* result);
static int get_erlang_integer(LoaderState* stp, Uint len_code, BeamInstr* result);
static int new_label(LoaderState* stp);
static void new_literal_patch(LoaderState* stp, int pos);
static void new_string_patch(LoaderState* stp, int pos);
static Uint new_literal(LoaderState* stp, Eterm** hpp, Uint heap_size);
static int genopargcompare(GenOpArg* a, GenOpArg* b);
static Eterm exported_from_module(Process* p, Eterm mod);
static Eterm functions_in_module(Process* p, Eterm mod);
static Eterm attributes_for_module(Process* p, Eterm mod);
static Eterm compilation_info_for_module(Process* p, Eterm mod);
static Eterm native_addresses(Process* p, Eterm mod);
int patch_funentries(Eterm Patchlist);
int patch(Eterm Addresses, Uint fe);
static int safe_mul(UWord a, UWord b, UWord* resp);


static int must_swap_floats;

/*
 * The following variables keep a sorted list of address ranges for
 * each module.  It allows us to quickly find a function given an
 * instruction pointer.
 */
Range* modules = NULL;	    /* Sorted lists of module addresses. */
int num_loaded_modules;	    /* Number of loaded modules. */
int allocated_modules;	    /* Number of slots allocated. */
Range* mid_module = NULL;   /* Cached search start point */

Uint erts_total_code_size;
/**********************************************************************/


void init_load(void)
{
    FloatDef f;

    erts_total_code_size = 0;

    beam_catches_init();

    f.fd = 1.0;
    must_swap_floats = (f.fw[0] == 0);

    allocated_modules = 128;
    modules = (Range *) erts_alloc(ERTS_ALC_T_MODULE_REFS,
				   allocated_modules*sizeof(Range));
    mid_module = modules;
    num_loaded_modules = 0;
}

static void
define_file(LoaderState* stp, char* name, int idx)
{
    stp->file_name = name;
    stp->file_p = stp->chunks[idx].start;
    stp->file_left = stp->chunks[idx].size;
}

int
erts_load_module(Process *c_p,
		 ErtsProcLocks c_p_locks,
		 Eterm group_leader, /* Group leader or NIL if none. */
		 Eterm* modp,	/*
				 * Module name as an atom (NIL to not check).
				 * On return, contains the actual module name.
				 */
		 byte* code,	/* Points to the code to load */
		 int size)	/* Size of code to load. */
{
    ErlDrvBinary* bin;
    int result;

    if (size >= 4 && code[0] == 'F' && code[1] == 'O' &&
	code[2] == 'R' && code[3] == '1') {
	/*
	 * The BEAM module is not compressed.
	 */
	result = bin_load(c_p, c_p_locks, group_leader, modp, code, size);
    } else {
	/*
	 * The BEAM module is compressed (or possibly invalid/corrupted).
	 */
	if ((bin = (ErlDrvBinary *) erts_gzinflate_buffer((char*)code, size)) == NULL) {
	    return -1;
	}
	result = bin_load(c_p, c_p_locks, group_leader, modp,
			  (byte*)bin->orig_bytes, bin->orig_size);
	driver_free_binary(bin);
    }
    return result;
}
/* #define LOAD_MEMORY_HARD_DEBUG 1*/

#if defined(LOAD_MEMORY_HARD_DEBUG) && defined(DEBUG)
/* Requires allocators ERTS_ALLOC_UTIL_HARD_DEBUG also set in erl_alloc_util.h */
extern void check_allocators(void);
extern void check_allocated_block(Uint type, void *blk);
#define CHKALLOC() check_allocators()
#define CHKBLK(TYPE,BLK) if ((BLK) != NULL) check_allocated_block((TYPE),(BLK))
#else
#define CHKALLOC() /* nothing */
#define CHKBLK(TYPE,BLK) /* nothing */
#endif

static int
bin_load(Process *c_p, ErtsProcLocks c_p_locks,
	 Eterm group_leader, Eterm* modp, byte* bytes, int unloaded_size)
{
    LoaderState state;
    int rval = -1;

    init_state(&state);
    state.module = *modp;
    state.group_leader = group_leader;

    /*
     * Scan the IFF file.
     */

#if defined(LOAD_MEMORY_HARD_DEBUG) && defined(DEBUG)
    erts_fprintf(stderr,"Loading a module\n");
#endif

    CHKALLOC();
    CHKBLK(ERTS_ALC_T_CODE,state.code);
    state.file_name = "IFF header for Beam file";
    state.file_p = bytes;
    state.file_left = unloaded_size;
    if (!scan_iff_file(&state, chunk_types, NUM_CHUNK_TYPES, NUM_MANDATORY)) {
	goto load_error;
    }

    /*
     * Read the header for the code chunk.
     */

    CHKBLK(ERTS_ALC_T_CODE,state.code);
    define_file(&state, "code chunk header", CODE_CHUNK);
    if (!read_code_header(&state)) {
	goto load_error;
    }

    /*
     * Read the atom table.
     */

    CHKBLK(ERTS_ALC_T_CODE,state.code);
    define_file(&state, "atom table", ATOM_CHUNK);
    if (!load_atom_table(&state)) {
	goto load_error;
    }

    /*
     * Read the import table.
     */

    CHKBLK(ERTS_ALC_T_CODE,state.code);
    define_file(&state, "import table", IMP_CHUNK);
    if (!load_import_table(&state)) {
	goto load_error;
    }

    /*
     * Read the lambda (fun) table.
     */

    CHKBLK(ERTS_ALC_T_CODE,state.code);
    if (state.chunks[LAMBDA_CHUNK].size > 0) {
	define_file(&state, "lambda (fun) table", LAMBDA_CHUNK);
	if (!read_lambda_table(&state)) {
	    goto load_error;
	}
    }

    /*
     * Read the literal table.
     */

    CHKBLK(ERTS_ALC_T_CODE,state.code);
    if (state.chunks[LITERAL_CHUNK].size > 0) {
	define_file(&state, "literals table (constant pool)", LITERAL_CHUNK);
	if (!read_literal_table(&state)) {
	    goto load_error;
	}
    }

    /*
     * Load the code chunk.
     */

    CHKBLK(ERTS_ALC_T_CODE,state.code);
    state.file_name = "code chunk";
    state.file_p = state.code_start;
    state.file_left = state.code_size;
    if (!load_code(&state)) {
	goto load_error;
    }
    CHKBLK(ERTS_ALC_T_CODE,state.code);
    if (!freeze_code(&state)) {
	goto load_error;
    }


    /*
     * Read and validate the export table.  (This must be done after
     * loading the code, because it contains labels.)
     */
    
    CHKBLK(ERTS_ALC_T_CODE,state.code);
    define_file(&state, "export table", EXP_CHUNK);
    if (!read_export_table(&state)) {
	goto load_error;
    }

    /*
     * Ready for the final touch: fixing the export table entries for
     * exported and imported functions.  This can't fail.
     */
    
    CHKBLK(ERTS_ALC_T_CODE,state.code);
    rval = insert_new_code(c_p, c_p_locks, state.group_leader, state.module,
			   state.code, state.loaded_size, state.catches);
    if (rval < 0) {
	goto load_error;
    }
    CHKBLK(ERTS_ALC_T_CODE,state.code);
    final_touch(&state);

    /*
     * Loading succeded.
     */
    CHKBLK(ERTS_ALC_T_CODE,state.code);
#if defined(LOAD_MEMORY_HARD_DEBUG) && defined(DEBUG)
    erts_fprintf(stderr,"Loaded %T\n",*modp);
#if 0
    debug_dump_code(state.code,state.ci);
#endif
#endif
    rval = 0;
    state.code = NULL;		/* Prevent code from being freed. */
    *modp = state.module;

    /*
     * If there is an on_load function, signal an error to
     * indicate that the on_load function must be run.
     */
    if (state.on_load) {
	rval = -5;
    }

 load_error:
    if (state.code != 0) {
	erts_free(ERTS_ALC_T_CODE, state.code);
    }
    if (state.labels != NULL) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.labels);
    }
    if (state.atom != NULL) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.atom);
    }
    if (state.import != NULL) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.import);
    }
    if (state.export != NULL) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.export);
    }
    if (state.lambdas != state.def_lambdas) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.lambdas);
    }
    if (state.literals != NULL) {
	int i;
	for (i = 0; i < state.num_literals; i++) {
	    if (state.literals[i].heap != NULL) {
		erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.literals[i].heap);
	    }
	}
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.literals);
    }
    while (state.literal_patches != NULL) {
	LiteralPatch* next = state.literal_patches->next;
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.literal_patches);
	state.literal_patches = next;
    }
    while (state.string_patches != NULL) {
	StringPatch* next = state.string_patches->next;
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.string_patches);
	state.string_patches = next;
    }
    while (state.genop_blocks) {
	GenOpBlock* next = state.genop_blocks->next;
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.genop_blocks);
	state.genop_blocks = next;
    }

    return rval;
}


static void
init_state(LoaderState* stp)
{
    stp->function = THE_NON_VALUE; /* Function not known yet */
    stp->arity = 0;
    stp->specific_op = -1;
    stp->genop = NULL;
    stp->atom = NULL;
    stp->code = NULL;
    stp->labels = NULL;
    stp->import = NULL;
    stp->export = NULL;
    stp->free_genop = NULL;
    stp->genop_blocks = NULL;
    stp->num_lambdas = 0;
    stp->lambdas_allocated = sizeof(stp->def_lambdas)/sizeof(Lambda);
    stp->lambdas = stp->def_lambdas;
    stp->lambda_error = NULL;
    stp->num_literals = 0;
    stp->allocated_literals = 0;
    stp->literals = 0;
    stp->total_literal_size = 0;
    stp->literal_patches = 0;
    stp->string_patches = 0;
    stp->new_float_instructions = 0;
    stp->may_load_nif = 0;
    stp->on_load = 0;
}

static int
insert_new_code(Process *c_p, ErtsProcLocks c_p_locks,
		Eterm group_leader, Eterm module, BeamInstr* code, Uint size, BeamInstr catches)
{
    Module* modp;
    int rval;
    int i;

    if ((rval = beam_make_current_old(c_p, c_p_locks, module)) < 0) {
	erts_dsprintf_buf_t *dsbufp = erts_create_logger_dsbuf();
	erts_dsprintf(dsbufp,
		      "Module %T must be purged before loading\n",
		      module);
	erts_send_error_to_logger(group_leader, dsbufp);
	return rval;
    }

    /*
     * Update module table.
     */

    erts_total_code_size += size;
    modp = erts_put_module(module);
    modp->code = code;
    modp->code_length = size;
    modp->catches = catches;

    /*
     * Update address table (used for finding a function from a PC value).
     */

    if (num_loaded_modules == allocated_modules) {
	allocated_modules *= 2;
	modules = (Range *) erts_realloc(ERTS_ALC_T_MODULE_REFS,
					 (void *) modules,
					 allocated_modules * sizeof(Range));
    }
    for (i = num_loaded_modules; i > 0; i--) {
	if (code > modules[i-1].start) {
	    break;
	}
	modules[i] = modules[i-1];
    }
    modules[i].start = code;
    modules[i].end = (BeamInstr *) (((byte *)code) + size);
    num_loaded_modules++;
    mid_module = &modules[num_loaded_modules/2];
    return 0;
}

static int
scan_iff_file(LoaderState* stp, Uint* chunk_types, Uint num_types, Uint num_mandatory)
{
    MD5_CTX context;
    Uint id;
    Uint count;
    int i;

    /*
     * The binary must start with an IFF 'FOR1' chunk.
     */

    GetInt(stp, 4, id);
    if (id != MakeIffId('F', 'O', 'R', '1')) {
	LoadError0(stp, "not a BEAM file: no IFF 'FOR1' chunk");
    }

    /*
     * Retrieve the chunk size and verify it.  If the size is equal to
     * or less than the size of the binary, it is ok and we will use it
     * as the limit for the logical file size.
     */

    GetInt(stp, 4, count);
    if (count > stp->file_left) {
	LoadError2(stp, "form size %ld greater than size %ld of binary",
		  count, stp->file_left);
    }
    stp->file_left = count;

    /*
     * Verify that this is a BEAM file.
     */

    GetInt(stp, 4, id);
    if (id != MakeIffId('B', 'E', 'A', 'M')) {
	LoadError0(stp, "not a BEAM file: IFF form type is not 'BEAM'");
    }

    /*
     * Initialize the chunks[] array in the state.
     */

    for (i = 0; i < num_types; i++) {
	stp->chunks[i].start = NULL;
	stp->chunks[i].size = 0;
    }

    /*
     * Now we can go ahead and read all chunks in the BEAM form.
     */

    while (!EndOfFile(stp)) {

	/*
	 * Read the chunk id and verify that it contains ASCII characters.
	 */
	GetInt(stp, 4, id);
	for (i = 0; i < 4; i++) {
	    unsigned c = (id >> i*8) & 0xff;
	    if (c < ' ' || c > 0x7E) {
		LoadError1(stp, "non-ascii garbage '%lx' instead of chunk type id",
			   id);
	    }
	}

	/*
	 * Read the count and verify it.
	 */

	GetInt(stp, 4, count);
	if (count > stp->file_left) {
	    LoadError2(stp, "chunk size %ld for '%lx' greater than size %ld of binary",
		       count, stp->file_left);
	}

	/*
	 * See if the chunk is useful for the loader.
	 */
	for (i = 0; i < num_types; i++) {
	    if (chunk_types[i] == id) {
		stp->chunks[i].start = stp->file_p;
		stp->chunks[i].size = count;
		break;
	    }
	}

	/*
	 * Go on to the next chunk.
	 */
	count = 4*((count+3)/4);
	stp->file_p += count;
	stp->file_left -= count;
    }

    /*
     * At this point, we have read the entire IFF file, and we
     * know that it is syntactically correct.
     *
     * Now check that it contains all mandatory chunks. At the
     * same time calculate the MD5 for the module.
     */

    MD5Init(&context);
    for (i = 0; i < num_mandatory; i++) {
	if (stp->chunks[i].start != NULL) {
	    MD5Update(&context, stp->chunks[i].start, stp->chunks[i].size);
	} else {
	    char sbuf[5];

	    id_to_string(chunk_types[i], sbuf);
	    LoadError1(stp, "mandatory chunk of type '%s' not found\n", sbuf);
	}
    }
    if (LITERAL_CHUNK < num_types) {
	if (stp->chunks[LAMBDA_CHUNK].start != 0) {
	    byte* start = stp->chunks[LAMBDA_CHUNK].start;
	    Uint left = stp->chunks[LAMBDA_CHUNK].size;

	    /*
	     * The idea here is to ignore the OldUniq field for the fun; it is
	     * based on the old broken hash function, which can be different
	     * on little endian and big endian machines.
	     */
	    if (left >= 4) {
		static byte zero[4];
		MD5Update(&context, start, 4);
		start += 4;
		left -= 4;
		
		while (left >= 24) {
		    /* Include: Function Arity Index NumFree */
		    MD5Update(&context, start, 20);
		    /* Set to zero: OldUniq */
		    MD5Update(&context, zero, 4);
		    start += 24;
		    left -= 24;
		}
	    }
	    /* Can't happen for a correct 'FunT' chunk */
	    if (left > 0) {
		MD5Update(&context, start, left);
	    }
	}
	if (stp->chunks[LITERAL_CHUNK].start != 0) {
	    MD5Update(&context, stp->chunks[LITERAL_CHUNK].start,
		      stp->chunks[LITERAL_CHUNK].size);
	}
    }
    MD5Final(stp->mod_md5, &context);
    return 1;

 load_error:
    return 0;
}


static int
load_atom_table(LoaderState* stp)
{
    int i;

    GetInt(stp, 4, stp->num_atoms);
    stp->num_atoms++;
    stp->atom = erts_alloc(ERTS_ALC_T_LOADER_TMP,
			   erts_next_heap_size((stp->num_atoms*sizeof(Eterm)),
					       0));

    /*
     * Read all atoms.
     */

    for (i = 1; i < stp->num_atoms; i++) {
	byte* atom;
	Uint n;

	GetByte(stp, n);
	GetString(stp, atom, n);
	stp->atom[i] = am_atom_put((char*)atom, n);
    }

    /*
     * Check the module name if a module name was given.
     */

    if (is_nil(stp->module)) {
	stp->module = stp->atom[1];
    } else if (stp->atom[1] != stp->module) {
	char sbuf[256];
	Atom* ap;

	ap = atom_tab(atom_val(stp->atom[1]));
	memcpy(sbuf, ap->name, ap->len);
	sbuf[ap->len] = '\0';
	LoadError1(stp, "module name in object code is %s", sbuf);
    }

    return 1;

 load_error:
    return 0;
}


static int
load_import_table(LoaderState* stp)
{
    int i;

    GetInt(stp, 4, stp->num_imports);
    stp->import = erts_alloc(ERTS_ALC_T_LOADER_TMP,
			     erts_next_heap_size((stp->num_imports *
						  sizeof(ImportEntry)),
						 0));
    for (i = 0; i < stp->num_imports; i++) {
	int n;
	Eterm mod;
	Eterm func;
	Uint arity;
	Export* e;

	GetInt(stp, 4, n);
	if (n >= stp->num_atoms) {
	    LoadError2(stp, "import entry %d: invalid atom number %d", i, n);
	}
	mod = stp->import[i].module = stp->atom[n];
	GetInt(stp, 4, n);
	if (n >= stp->num_atoms) {
	    LoadError2(stp, "import entry %d: invalid atom number %d", i, n);
	}
	func = stp->import[i].function = stp->atom[n];
	GetInt(stp, 4, arity);
	if (arity > MAX_REG) {
	    LoadError2(stp, "import entry %d: invalid arity %d", i, arity);
	}
	stp->import[i].arity = arity;
	stp->import[i].patches = 0;
	stp->import[i].bf = NULL;

	/*
	 * If the export entry refers to a BIF, get the pointer to
	 * the BIF function.
	 */
	if ((e = erts_find_export_entry(mod, func, arity)) != NULL) {
	    if (e->code[3] == (BeamInstr) em_apply_bif) {
		stp->import[i].bf = (BifFunction) e->code[4];
		if (func == am_load_nif && mod == am_erlang && arity == 2) {
		    stp->may_load_nif = 1;
		}
	    }
	}
    }
    return 1;

 load_error:
    return 0;
}


static int
read_export_table(LoaderState* stp)
{
    static struct {
	Eterm mod;
	Eterm func;
	int arity;
    } allow_redef[] = {
	/* The BIFs that are allowed to be redefined by Erlang code */
	{am_erlang,am_apply,2},
	{am_erlang,am_apply,3},
    };
    int i;

    GetInt(stp, 4, stp->num_exps);
    if (stp->num_exps > stp->num_functions) {
	LoadError2(stp, "%d functions exported; only %d functions defined",
		   stp->num_exps, stp->num_functions);
    }
    stp->export
	= (ExportEntry *) erts_alloc(ERTS_ALC_T_LOADER_TMP,
				     (stp->num_exps * sizeof(ExportEntry)));

    for (i = 0; i < stp->num_exps; i++) {
	Uint n;
	Uint value;
	Eterm func;
	Uint arity;
	Export* e;

	GetInt(stp, 4, n);
	GetAtom(stp, n, func);
	stp->export[i].function = func;
	GetInt(stp, 4, arity);
	if (arity > MAX_REG) {
	    LoadError2(stp, "export table entry %d: absurdly high arity %d", i, arity);
	}
	stp->export[i].arity = arity;
	GetInt(stp, 4, n);
	if (n >= stp->num_labels) {
	    LoadError3(stp, "export table entry %d: invalid label %d (highest defined label is %d)", i, n, stp->num_labels);
	}
	value = stp->labels[n].value;
	if (value == 0) {
	    LoadError2(stp, "export table entry %d: label %d not resolved", i, n);
	}
	stp->export[i].address = stp->code + value;

	/*
	 * Check that we are not redefining a BIF (except the ones allowed to
	 * redefine).
	 */
	if ((e = erts_find_export_entry(stp->module, func, arity)) != NULL) {
	    if (e->code[3] == (BeamInstr) em_apply_bif) {
		int j;

		for (j = 0; j < sizeof(allow_redef)/sizeof(allow_redef[0]); j++) {
		    if (stp->module == allow_redef[j].mod &&
			func == allow_redef[j].func &&
			arity == allow_redef[j].arity) {
			break;
		    }
		}
		if (j == sizeof(allow_redef)/sizeof(allow_redef[0])) {
		    LoadError2(stp, "exported function %T/%d redefines BIF",
			       func, arity);
		}
	    }
	}
    }
    return 1;

 load_error:
    return 0;
}

static int
read_lambda_table(LoaderState* stp)
{
    int i;

    GetInt(stp, 4, stp->num_lambdas);
    stp->lambdas_allocated = stp->num_lambdas;
    stp->lambdas = (Lambda *) erts_alloc(ERTS_ALC_T_LOADER_TMP,
					 stp->num_lambdas * sizeof(Lambda));
    for (i = 0; i < stp->num_lambdas; i++) {
	Uint n;
	Uint32 Index;
	Uint32 OldUniq;
	ErlFunEntry* fe;
	Uint arity;

	GetInt(stp, 4, n);	/* Function. */
	GetAtom(stp, n, stp->lambdas[i].function);
	GetInt(stp, 4, arity);
	if (arity > MAX_REG) {
	    LoadError2(stp, "lambda entry %d: absurdly high arity %d", i, arity);
	}
	stp->lambdas[i].arity = arity;
	GetInt(stp, 4, n);
	if (n >= stp->num_labels) {
	    LoadError3(stp, "lambda entry %d: invalid label %d (highest defined label is %d)",
		       i, n, stp->num_labels);
	}
	stp->lambdas[i].label = n;
	GetInt(stp, 4, Index);
	GetInt(stp, 4, stp->lambdas[i].num_free);
	GetInt(stp, 4, OldUniq);
	fe = erts_put_fun_entry2(stp->module, OldUniq, i, stp->mod_md5,
				 Index, arity-stp->lambdas[i].num_free);
	stp->lambdas[i].fe = fe;
    }
    return 1;

 load_error:
    return 0;
}

static int
read_literal_table(LoaderState* stp)
{
    int i;
    BeamInstr uncompressed_sz;
    byte* uncompressed = 0;

    GetInt(stp, 4, uncompressed_sz);
    uncompressed = erts_alloc(ERTS_ALC_T_TMP, uncompressed_sz);
    if (erl_zlib_uncompress(uncompressed, &uncompressed_sz,
		   stp->file_p, stp->file_left) != Z_OK) {
	LoadError0(stp, "failed to uncompress literal table (constant pool)");
    }
    stp->file_p = uncompressed;
    stp->file_left = uncompressed_sz;
    GetInt(stp, 4, stp->num_literals);
    stp->literals = (Literal *) erts_alloc(ERTS_ALC_T_LOADER_TMP,
					   stp->num_literals * sizeof(Literal));
    stp->allocated_literals = stp->num_literals;

    for (i = 0; i < stp->num_literals; i++) {
	stp->literals[i].heap = 0;
    }

    for (i = 0; i < stp->num_literals; i++) {
	int sz;
	Sint heap_size;
	byte* p;
	Eterm val;
	Eterm* hp;

	GetInt(stp, 4, sz);	/* Size of external term format. */
	GetString(stp, p, sz);
	if ((heap_size = erts_decode_ext_size(p, sz, 1)) < 0) {
	    LoadError1(stp, "literal %d: bad external format", i);
	}
	hp = stp->literals[i].heap = erts_alloc(ERTS_ALC_T_LOADER_TMP,
						heap_size*sizeof(Eterm));
	val = erts_decode_ext(&hp, NULL, &p);
	stp->literals[i].heap_size = hp - stp->literals[i].heap;
	if (stp->literals[i].heap_size > heap_size) {
	    erl_exit(1, "overrun by %d word(s) for literal heap, term %d",
		     stp->literals[i].heap_size - heap_size, i);
	}
	if (is_non_value(val)) {
	    LoadError1(stp, "literal %d: bad external format", i);
	}
	stp->literals[i].term = val;
	stp->total_literal_size += stp->literals[i].heap_size;
    }
    erts_free(ERTS_ALC_T_TMP, uncompressed);
    return 1;

 load_error:
    if (uncompressed) {
	erts_free(ERTS_ALC_T_TMP, uncompressed);
    }
    return 0;
}


static int
read_code_header(LoaderState* stp)
{
    unsigned head_size;
    unsigned version;
    unsigned opcode_max;
    int i;

    /*
     * Read size of sub-header for code information and from it calculate
     * where the code begins.  Also, use the size to limit the file size
     * for header reading, so that we automatically get an error if the
     * size is set too small.
     */

    GetInt(stp, 4, head_size);
    stp->code_start = stp->file_p + head_size;
    stp->code_size = stp->file_left - head_size;
    stp->file_left = head_size;

    /*
     * Get and verify version of instruction set.
     */

    GetInt(stp, 4, version);
    if (version != BEAM_FORMAT_NUMBER) {
	LoadError2(stp, "wrong instruction set %d; expected %d",
		   version, BEAM_FORMAT_NUMBER);
    }

    /*
     * Verify the number of the highest opcode used.
     */

    GetInt(stp, 4, opcode_max);
    if (opcode_max > MAX_GENERIC_OPCODE) {
	LoadError2(stp, "use of opcode %d; this emulator supports only up to %d",
		   opcode_max, MAX_GENERIC_OPCODE);
    }

    GetInt(stp, 4, stp->num_labels);
    GetInt(stp, 4, stp->num_functions);

    /*
     * Initialize label table.
     */

    stp->labels = (Label *) erts_alloc(ERTS_ALC_T_LOADER_TMP,
				       stp->num_labels * sizeof(Label));
    for (i = 0; i < stp->num_labels; i++) {
	stp->labels[i].value = 0;
	stp->labels[i].patches = 0;
#ifdef ERTS_SMP
	stp->labels[i].looprec_targeted = 0;
#endif
    }

    /*
     * Initialize code area.
     */
    stp->code_buffer_size = erts_next_heap_size(2048 + stp->num_functions, 0);
    stp->code = (BeamInstr *) erts_alloc(ERTS_ALC_T_CODE,
				    sizeof(BeamInstr) * stp->code_buffer_size);

    stp->code[MI_NUM_FUNCTIONS] = stp->num_functions;
    stp->ci = MI_FUNCTIONS + stp->num_functions + 1;

    stp->code[MI_ATTR_PTR] = 0;
    stp->code[MI_ATTR_SIZE] = 0;
    stp->code[MI_ATTR_SIZE_ON_HEAP] = 0;
    stp->code[MI_COMPILE_PTR] = 0;
    stp->code[MI_COMPILE_SIZE] = 0;
    stp->code[MI_COMPILE_SIZE_ON_HEAP] = 0;
    stp->code[MI_NUM_BREAKPOINTS] = 0;

    stp->new_bs_put_strings = 0;
    stp->catches = 0;
    return 1;

 load_error:
    return 0;
}


#define VerifyTag(Stp, Actual, Expected) \
    if (Actual != Expected) { \
       LoadError2(Stp, "bad tag %d; expected %d", Actual, Expected); \
    } else {}

#define CodeNeed(w) do {						\
    ASSERT(ci <= code_buffer_size);					\
    if (code_buffer_size < ci+(w)) {					\
        code_buffer_size = erts_next_heap_size(ci+(w), 0);		\
	stp->code = code						\
	    = (BeamInstr *) erts_realloc(ERTS_ALC_T_CODE,			\
				     (void *) code,			\
				     code_buffer_size * sizeof(BeamInstr));	\
    } 									\
} while (0)
    
#define TermWords(t) (((t) / (sizeof(BeamInstr)/sizeof(Eterm))) + !!((t) % (sizeof(BeamInstr)/sizeof(Eterm))))


static int
load_code(LoaderState* stp)
{
    int i;
    int tmp;
    int ci;
    int last_func_start = 0;
    char* sign;
    int arg;			/* Number of current argument. */
    int num_specific;		/* Number of specific ops for current. */
    BeamInstr* code;
    int code_buffer_size;
    int specific;
    Uint last_label = 0;	/* Number of last label. */
    Uint function_number = 0;
    GenOp* last_op = NULL;
    GenOp** last_op_next = NULL;
    int arity;

    code = stp->code;
    code_buffer_size = stp->code_buffer_size;
    ci = stp->ci;

    for (;;) {
	int new_op;
	GenOp* tmp_op;

	ASSERT(ci <= code_buffer_size);

    get_next_instr:
	GetByte(stp, new_op);
	if (new_op >= NUM_GENERIC_OPS) {
	    LoadError1(stp, "invalid opcode %d", new_op);
	}
	if (gen_opc[new_op].name[0] == '\0') {
	    LoadError1(stp, "invalid opcode %d", new_op);
	}
				       

	/*
	 * Create a new generic operation and put it last in the chain.
	 */
	if (last_op_next == NULL) {
	    last_op_next = &(stp->genop);
	    while (*last_op_next != NULL) {
		last_op_next = &(*last_op_next)->next;
	    }
	}

	NEW_GENOP(stp, last_op);
	last_op->next = NULL;
	last_op->op = new_op;
	*last_op_next = last_op;
	last_op_next = &(last_op->next);
	stp->specific_op = -1;

	/*
	 * Read all arguments for the current operation.
	 */

	arity = gen_opc[last_op->op].arity;
	last_op->arity = 0;
	ASSERT(arity <= MAX_OPARGS);

#define GetValue(Stp, First, Val) \
   do { \
      if (((First) & 0x08) == 0) { \
	 Val = (First) >> 4; \
      } else if (((First) & 0x10) == 0) { \
         BeamInstr __w; \
	 GetByte(Stp, __w); \
	 Val = (((First) >> 5) << 8) | __w; \
      } else { \
	if (!get_int_val(Stp, (First), &(Val))) goto load_error; \
      } \
   } while (0)

	for (arg = 0; arg < arity; arg++) {
	    BeamInstr first;

	    GetByte(stp, first);
	    last_op->a[arg].type = first & 0x07;
	    switch (last_op->a[arg].type) {
	    case TAG_i:
		if ((first & 0x08) == 0) {
		    last_op->a[arg].val = first >> 4;
		} else if ((first & 0x10) == 0) {
		    BeamInstr w;
		    GetByte(stp, w);
		    ASSERT(first < 0x800);
		    last_op->a[arg].val = ((first >> 5) << 8) | w;
		} else {
		    int i = get_erlang_integer(stp, first, &(last_op->a[arg].val));
		    if (i < 0) {
			goto load_error;
		    }
		    last_op->a[arg].type = i;
		}
		break;
	    case TAG_u:
		GetValue(stp, first, last_op->a[arg].val);
		break;
	    case TAG_x:
		GetValue(stp, first, last_op->a[arg].val);
		if (last_op->a[arg].val == 0) {
		    last_op->a[arg].type = TAG_r;
		} else if (last_op->a[arg].val >= MAX_REG) {
		    LoadError1(stp, "invalid x register number: %u",
			       last_op->a[arg].val);
		}
		break;
	    case TAG_y:
		GetValue(stp, first, last_op->a[arg].val);
		if (last_op->a[arg].val >= MAX_REG) {
		    LoadError1(stp, "invalid y register number: %u",
			       last_op->a[arg].val);
		}
		last_op->a[arg].val += CP_SIZE;
		break;
	    case TAG_a:
		GetValue(stp, first, last_op->a[arg].val);
		if (last_op->a[arg].val == 0) {
		    last_op->a[arg].type = TAG_n;
		} else if (last_op->a[arg].val >= stp->num_atoms) {
		    LoadError1(stp, "bad atom index: %d", last_op->a[arg].val);
		} else {
		    last_op->a[arg].val = stp->atom[last_op->a[arg].val];
		}
		break;
	    case TAG_f:
		GetValue(stp, first, last_op->a[arg].val);
		if (last_op->a[arg].val == 0) {
		    last_op->a[arg].type = TAG_p;
		} else if (last_op->a[arg].val >= stp->num_labels) {
		    LoadError1(stp, "bad label: %d", last_op->a[arg].val);
		}
		break;
	    case TAG_h:
		GetValue(stp, first, last_op->a[arg].val);
		if (last_op->a[arg].val > 65535) {
		    LoadError1(stp, "invalid range for character data type: %u",
			       last_op->a[arg].val);
		}
		break;
	    case TAG_z:
		{
		    BeamInstr ext_tag;
		    unsigned tag;

		    GetValue(stp, first, ext_tag);
		    switch (ext_tag) {
		    case 0:	/* Floating point number */
			{
			    Eterm* hp;
/* XXX:PaN - Halfword should use ARCH_64 variant instead */
#if !defined(ARCH_64) || HALFWORD_HEAP
			    Uint high, low;
# endif
			    last_op->a[arg].val = new_literal(stp, &hp,
							      FLOAT_SIZE_OBJECT);
			    hp[0] = HEADER_FLONUM;
			    last_op->a[arg].type = TAG_q;
#if defined(ARCH_64) && !HALFWORD_HEAP
			    GetInt(stp, 8, hp[1]);
# else
			    GetInt(stp, 4, high);
			    GetInt(stp, 4, low);
			    if (must_swap_floats) {
				Uint t = high;
				high = low;
				low = t;
			    }
			    hp[1] = high;
			    hp[2] = low;
# endif
			}
			break;
		    case 1:	/* List. */
			if (arg+1 != arity) {
			    LoadError0(stp, "list argument must be the last argument");
			}
			GetTagAndValue(stp, tag, last_op->a[arg].val);
			VerifyTag(stp, tag, TAG_u);
			last_op->a[arg].type = TAG_u;
			last_op->a =
			    erts_alloc(ERTS_ALC_T_LOADER_TMP,
				       (arity+last_op->a[arg].val)
				       *sizeof(GenOpArg));
			memcpy(last_op->a, last_op->def_args,
			       arity*sizeof(GenOpArg));
			arity += last_op->a[arg].val;
			break;
		    case 2:	/* Float register. */
			GetTagAndValue(stp, tag, last_op->a[arg].val);
			VerifyTag(stp, tag, TAG_u);
			last_op->a[arg].type = TAG_l;
			break;
		    case 3: 	/* Allocation list. */
			{
			    BeamInstr n;
			    BeamInstr type;
			    BeamInstr val;
			    BeamInstr words = 0;
			    
			    stp->new_float_instructions = 1;
			    GetTagAndValue(stp, tag, n);
			    VerifyTag(stp, tag, TAG_u);
			    while (n-- > 0) {
				GetTagAndValue(stp, tag, type);
				VerifyTag(stp, tag, TAG_u);
				GetTagAndValue(stp, tag, val);
				VerifyTag(stp, tag, TAG_u);
				switch (type) {
				case 0:	/* Heap words */
				    words += val;
				    break;
				case 1:
				    words += FLOAT_SIZE_OBJECT*val;
				    break;
				default:
				    LoadError1(stp, "alloc list: bad allocation "
					       "descriptor %d", type);
				    break;
				}
			    }
			    last_op->a[arg].type = TAG_u;
			    last_op->a[arg].val = words;
			    break;
			}
		    case 4:	/* Literal. */
			{
			    BeamInstr val;

			    GetTagAndValue(stp, tag, val);
			    VerifyTag(stp, tag, TAG_u);
			    if (val >= stp->num_literals) {
				LoadError1(stp, "bad literal index %d", val);
			    }
			    last_op->a[arg].type = TAG_q;
			    last_op->a[arg].val = val;
			    break;
			}
		    default:
			LoadError1(stp, "invalid extended tag %d", ext_tag);
			break;
		    }
		}
		break;
	    default:
		LoadError1(stp, "bad tag %d", last_op->a[arg].type);
		break;
	    }
	    last_op->arity++;
	}
#undef GetValue

	ASSERT(arity == last_op->arity);

    do_transform:
	if (stp->genop == NULL) {
	    last_op_next = NULL;
	    goto get_next_instr;
	}

	if (gen_opc[stp->genop->op].transform != -1) {
	    int need;
	    tmp_op = stp->genop;

	    for (need = gen_opc[stp->genop->op].min_window-1; need > 0; need--) {
		if (tmp_op == NULL) {
		    goto get_next_instr;
		}
		tmp_op = tmp_op->next;
	    }
	    switch (transform_engine(stp)) {
	    case TE_FAIL:
		last_op_next = NULL;
		last_op = NULL;
		break;
	    case TE_OK:
		last_op_next = NULL;
		last_op = NULL;
		goto do_transform;
	    case TE_SHORT_WINDOW:
		last_op_next = NULL;
		last_op = NULL;
		goto get_next_instr;
	    }
	}

	if (stp->genop == NULL) {
	    last_op_next = NULL;
	    goto get_next_instr;
	}

	/*
	 * Special error message instruction.
	 */
	if (stp->genop->op == genop_too_old_compiler_0) {
	    LoadError0(stp, "please re-compile this module with an " 
		       ERLANG_OTP_RELEASE " compiler");
	}

	/*
	 * From the collected generic instruction, find the specific
	 * instruction.
	 */

	{
	    Uint32 mask[3] = {0, 0, 0};

	    tmp_op = stp->genop;
	    arity = gen_opc[tmp_op->op].arity;
	    if (arity > 6) {
		LoadError0(stp, "no specific operation found (arity > 6)");
	    }
	    for (arg = 0; arg < arity; arg++) {
		mask[arg/2] |= ((Uint32)1 << (tmp_op->a[arg].type)) << ((arg%2)*16);
	    }
	    specific = gen_opc[tmp_op->op].specific;
	    num_specific = gen_opc[tmp_op->op].num_specific;
	    for (i = 0; i < num_specific; i++) {
		if (((opc[specific].mask[0] & mask[0]) == mask[0]) &&
		    ((opc[specific].mask[1] & mask[1]) == mask[1]) &&
		    ((opc[specific].mask[2] & mask[2]) == mask[2])) {
		    break;
		}
		specific++;
	    }

	    /*
	     * No specific operation found.
	     */
	    if (i == num_specific) {
		stp->specific_op = -1;
		for (arg = 0; arg < tmp_op->arity; arg++) {
		    /*
		     * We'll give the error message here (instead of earlier)
		     * to get a printout of the offending operation.
		     */
		    if (tmp_op->a[arg].type == TAG_h) {
			LoadError0(stp, "the character data type not supported");
		    }
		}

		/*
		 * No specific operations and no transformations means that
		 * the instruction is obsolete.
		 */
		if (num_specific == 0 && gen_opc[tmp_op->op].transform == -1) {
		    LoadError0(stp, "please re-compile this module with an "
			       ERLANG_OTP_RELEASE " compiler ");
		}

		LoadError0(stp, "no specific operation found");
	    }

	    stp->specific_op = specific;
	    CodeNeed(opc[stp->specific_op].sz+2); /* Extra margin for packing */
	    code[ci++] = BeamOpCode(stp->specific_op);
	}
	
	/*
	 * Load the found specific operation.
	 */

	sign = opc[stp->specific_op].sign;
	ASSERT(sign != NULL);
	arg = 0;
	while (*sign) {
	    Uint tag;

	    ASSERT(arg < stp->genop->arity);
	    tag = stp->genop->a[arg].type;
	    switch (*sign) {
	    case 'r':	/* x(0) */
	    case 'n':	/* Nil */
		VerifyTag(stp, tag_to_letter[tag], *sign);
		break;
	    case 'x':	/* x(N) */
	    case 'y':	/* y(N) */
		VerifyTag(stp, tag_to_letter[tag], *sign);
		code[ci++] = tmp_op->a[arg].val * sizeof(Eterm);
		break;
	    case 'a':		/* Tagged atom */
		VerifyTag(stp, tag_to_letter[tag], *sign);
		code[ci++] = tmp_op->a[arg].val;
		break;
	    case 'i':		/* Tagged integer */
		ASSERT(is_small(tmp_op->a[arg].val));
		VerifyTag(stp, tag_to_letter[tag], *sign);
		code[ci++] = tmp_op->a[arg].val;
		break;
	    case 'c':		/* Tagged constant */
		switch (tag) {
		case TAG_i:
		    code[ci++] = (BeamInstr) make_small((Uint) tmp_op->a[arg].val);
		    break;
		case TAG_a:
		    code[ci++] = tmp_op->a[arg].val;
		    break;
		case TAG_n:
		    code[ci++] = NIL;
		    break;
		case TAG_q:
		    new_literal_patch(stp, ci);
		    code[ci++] = tmp_op->a[arg].val;
		    break;
		default:
		    LoadError1(stp, "bad tag %d for tagged constant",
			       tmp_op->a[arg].type);
		    break;
		}
		break;
	    case 's':	/* Any source (tagged constant or register) */
		switch (tag) {
		case TAG_r:
		    code[ci++] = make_rreg();
		    break;
		case TAG_x:
		    code[ci++] = make_xreg(tmp_op->a[arg].val);
		    break;
		case TAG_y:
		    code[ci++] = make_yreg(tmp_op->a[arg].val);
		    break;
		case TAG_i:
		    code[ci++] = (BeamInstr) make_small((Uint)tmp_op->a[arg].val);
		    break;
		case TAG_a:
		    code[ci++] = tmp_op->a[arg].val;
		    break;
		case TAG_n:
		    code[ci++] = NIL;
		    break;
		default:
		    LoadError1(stp, "bad tag %d for general source",
			       tmp_op->a[arg].type);
		    break;
		}
		break;
	    case 'd':	/* Destination (x(0), x(N), y(N) */
		switch (tag) {
		case TAG_r:
		    code[ci++] = make_rreg();
		    break;
		case TAG_x:
		    code[ci++] = make_xreg(tmp_op->a[arg].val);
		    break;
		case TAG_y:
		    code[ci++] = make_yreg(tmp_op->a[arg].val);
		    break;
		default:
		    LoadError1(stp, "bad tag %d for destination",
			       tmp_op->a[arg].type);
		    break;
		}
		break;
	    case 'I':	/* Untagged integer (or pointer). */
		VerifyTag(stp, tag, TAG_u);
		code[ci++] = tmp_op->a[arg].val;
		break;
	    case 't':	/* Small untagged integer -- can be packed. */
		VerifyTag(stp, tag, TAG_u);
		code[ci++] = tmp_op->a[arg].val;
		break;
	    case 'A':	/* Arity value. */
		VerifyTag(stp, tag, TAG_u);
		code[ci++] = make_arityval(tmp_op->a[arg].val);
		break;
	    case 'f':		/* Destination label */
		VerifyTag(stp, tag_to_letter[tag], *sign);
		code[ci] = stp->labels[tmp_op->a[arg].val].patches;
		stp->labels[tmp_op->a[arg].val].patches = ci;
		ci++;
		break;
	    case 'j':		/* 'f' or 'p' */
		if (tag == TAG_p) {
		    code[ci] = 0;
		} else if (tag == TAG_f) {
		    code[ci] = stp->labels[tmp_op->a[arg].val].patches;
		    stp->labels[tmp_op->a[arg].val].patches = ci;
		} else {
		    LoadError3(stp, "bad tag %d; expected %d or %d",
			       tag, TAG_f, TAG_p);
		}
		ci++;
		break;
	    case 'L':		/* Define label */
		ci--;		/* Remove label from loaded code */
		ASSERT(stp->specific_op == op_label_L);
		VerifyTag(stp, tag, TAG_u);
		last_label = tmp_op->a[arg].val;
		if (!(0 < last_label && last_label < stp->num_labels)) {
		    LoadError2(stp, "invalid label num %d (0 < label < %d)",
			       tmp_op->a[arg].val, stp->num_labels);
		}
		if (stp->labels[last_label].value != 0) {
		    LoadError1(stp, "label %d defined more than once", last_label);
		}
		stp->labels[last_label].value = ci;
		ASSERT(stp->labels[last_label].patches < ci);
		break;
	    case 'e':		/* Export entry */
		VerifyTag(stp, tag, TAG_u);
		if (tmp_op->a[arg].val >= stp->num_imports) {
		    LoadError1(stp, "invalid import table index %d", tmp_op->a[arg].val);
		}
		code[ci] = stp->import[tmp_op->a[arg].val].patches;
		stp->import[tmp_op->a[arg].val].patches = ci;
		ci++;
		break;
	    case 'b':
		VerifyTag(stp, tag, TAG_u);
		i = tmp_op->a[arg].val;
		if (i >= stp->num_imports) {
		    LoadError1(stp, "invalid import table index %d", i);
		}
		if (stp->import[i].bf == NULL) {
		    LoadError1(stp, "not a BIF: import table index %d", i);
		}
		code[ci++] = (BeamInstr) stp->import[i].bf;
		break;
	    case 'P':		/* Byte offset into tuple */
		VerifyTag(stp, tag, TAG_u);
		tmp = tmp_op->a[arg].val;
		code[ci++] = (BeamInstr) ((tmp_op->a[arg].val+1) * sizeof(Eterm));
		break;
	    case 'l':		/* Floating point register. */
		VerifyTag(stp, tag_to_letter[tag], *sign);
		code[ci++] = tmp_op->a[arg].val * sizeof(FloatDef);
		break;
	    case 'q':		/* Literal */
		new_literal_patch(stp, ci);
		code[ci++] = tmp_op->a[arg].val;
		break;
	    default:
		LoadError1(stp, "bad argument tag: %d", *sign);
	    }
	    sign++;
	    arg++;
	}

	/*
	 * Load any list arguments using the primitive tags.
	 */

	for ( ; arg < tmp_op->arity; arg++) {
	    switch (tmp_op->a[arg].type) {
	    case TAG_i:
		CodeNeed(1);
		code[ci++] = make_small(tmp_op->a[arg].val);
		break;
	    case TAG_u:
	    case TAG_a:
	    case TAG_v:
		CodeNeed(1);
		code[ci++] = tmp_op->a[arg].val;
		break;
	    case TAG_f:
		CodeNeed(1);
		code[ci] = stp->labels[tmp_op->a[arg].val].patches;
		stp->labels[tmp_op->a[arg].val].patches = ci;
		ci++;
		break;
	    case TAG_q:
		{
		    Eterm lit;

		    lit = stp->literals[tmp_op->a[arg].val].term;
		    if (is_big(lit)) {
			Eterm* bigp;
			Eterm *tmp;
			Uint size;
			Uint term_size;

			bigp = big_val(lit);
			term_size = bignum_header_arity(*bigp);
			size = TermWords(term_size + 1);
			CodeNeed(size);
			tmp = (Eterm *) (code + ci);
			*tmp++ = *bigp++;
			while (term_size-- > 0) {
			    *tmp++ = *bigp++;
			}
			ci +=size;
		    } else if (is_float(lit)) {
#if defined(ARCH_64) && !HALFWORD_HEAP
			CodeNeed(1);
			code[ci++] = float_val(stp->literals[tmp_op->a[arg].val].term)[1];
#elif HALFWORD_HEAP
			Eterm* fptr;
			Uint size;
			Eterm *tmp;

			fptr = float_val(stp->literals[tmp_op->a[arg].val].term)+1;
			size = TermWords(2);
			CodeNeed(size);
			tmp = (Eterm *) (code + ci);
			*tmp++ = *fptr++;
			*tmp = *fptr;
			ci += size;
#else
			Eterm* fptr;

			fptr = float_val(stp->literals[tmp_op->a[arg].val].term)+1;
			CodeNeed(2);
			code[ci++] = *fptr++;
			code[ci++] = *fptr;
#endif
		    } else {
			LoadError0(stp, "literal is neither float nor big");
		    }
		}
		break;
	    default:
		LoadError1(stp, "unsupported primitive type '%c'",
			   tag_to_letter[tmp_op->a[arg].type]);
	    }
	}

	/*
	 * The packing engine.
	 */
	if (opc[stp->specific_op].pack[0]) {
	    char* prog;		/* Program for packing engine. */
	    BeamInstr stack[8];	/* Stack. */
	    BeamInstr* sp = stack;	/* Points to next free position. */
	    BeamInstr packed = 0;	/* Accumulator for packed operations. */

	    for (prog = opc[stp->specific_op].pack; *prog; prog++) {
		switch (*prog) {
		case 'g':	/* Get instruction; push on stack. */
		    *sp++ = code[--ci];
		    break;
		case 'i':	/* Initialize packing accumulator. */
		    packed = code[--ci];
		    break;
		case '0':	/* Tight shift */
		    packed = (packed << BEAM_TIGHT_SHIFT) | code[--ci];
		    break;
		case '6':	/* Shift 16 steps */
		    packed = (packed << BEAM_LOOSE_SHIFT) | code[--ci];
		    break;
		case 'p':	/* Put instruction (from stack). */
		    code[ci++] = *--sp;
		    break;
		case 'P':	/* Put packed operands. */
		    *sp++ = packed;
		    packed = 0;
		    break;
		default:
		    ASSERT(0);
		}
	    }
	    ASSERT(sp == stack); /* Incorrect program? */
	}

	/*
	 * Handle a few special cases.
	 */
	switch (stp->specific_op) {
	case op_i_func_info_IaaI:
	    {
		Uint offset;
		enum { FINFO_SZ = 5 };

		if (function_number >= stp->num_functions) {
		    LoadError1(stp, "too many functions in module (header said %d)",
			       stp->num_functions); 
		}

		if (stp->may_load_nif) {
		    const int finfo_ix = ci - FINFO_SZ;		    
		    enum { MIN_FUNC_SZ = 3 };		    
		    if (finfo_ix - last_func_start < MIN_FUNC_SZ && last_func_start) {		   
			/* Must make room for call_nif op */
			int pad = MIN_FUNC_SZ - (finfo_ix - last_func_start);
			ASSERT(pad > 0 && pad < MIN_FUNC_SZ);
			CodeNeed(pad);
			sys_memmove(&code[finfo_ix+pad], &code[finfo_ix], FINFO_SZ*sizeof(BeamInstr));
			sys_memset(&code[finfo_ix], 0, pad*sizeof(BeamInstr));
			ci += pad;
			stp->labels[last_label].value += pad;
		    }
		}
		last_func_start = ci;
		/*
		 * Save context for error messages.
		 */
		stp->function = code[ci-2];
		stp->arity = code[ci-1];

		ASSERT(stp->labels[last_label].value == ci - FINFO_SZ);
		offset = MI_FUNCTIONS + function_number;
		code[offset] = stp->labels[last_label].patches;
		stp->labels[last_label].patches = offset;
		function_number++;
		if (stp->arity > MAX_ARG) {
		    LoadError1(stp, "too many arguments: %d", stp->arity);
		}
#ifdef DEBUG
		ASSERT(stp->labels[0].patches == 0); /* Should not be referenced. */
		for (i = 1; i < stp->num_labels; i++) {
		    ASSERT(stp->labels[i].patches < ci);
		}
#endif
	    }
	    break;
	case op_on_load:
	    ci--;		/* Get rid of the instruction */

	    /* Remember offset for the on_load function. */
	    stp->on_load = ci;
	    break;
	case op_bs_put_string_II:
	    {
		/*
		 * At entry:
		 *
		 * code[ci-3]	&&lb_i_new_bs_put_string_II
		 * code[ci-2]	length of string
		 * code[ci-1]   offset into string table
		 *
		 * Since we don't know the address of the string table yet,
		 * just check the offset and length for validity, and use
		 * the instruction field as a link field to link all put_string
		 * instructions into a single linked list.  At exit:
		 *
		 * code[ci-3]	pointer to next i_new_bs_put_string instruction (or 0
		 *		if this is the last)
		 */
		Uint offset = code[ci-1];
		Uint len = code[ci-2];
		unsigned strtab_size = stp->chunks[STR_CHUNK].size;
		if (offset > strtab_size || offset + len > strtab_size) {
		    LoadError2(stp, "invalid string reference %d, size %d", offset, len);
		}
		code[ci-3] = stp->new_bs_put_strings;
		stp->new_bs_put_strings = ci - 3;
	    }
	    break;
	case op_i_bs_match_string_rfII:
	case op_i_bs_match_string_xfII:
	    new_string_patch(stp, ci-1);
	    break;

	case op_catch_yf:
	    /* code[ci-3]	&&lb_catch_yf
	     * code[ci-2]	y-register offset in E
	     * code[ci-1]	label; index tagged as CATCH at runtime
	     */
	    code[ci-3] = stp->catches;
	    stp->catches = ci-3;
	    break;

	    /*
	     * End of code found.
	     */
	case op_int_code_end:
	    stp->code_buffer_size = code_buffer_size;
	    stp->ci = ci;
	    return 1;
	}

	/*
	 * Delete the generic instruction just loaded.
	 */
	{
	    GenOp* next = stp->genop->next;
	    FREE_GENOP(stp, stp->genop);
	    stp->genop = next;
	    goto do_transform;
	}
    }
    

 load_error:
    return 0;
}


#define succ(St, X, Y) ((X).type == (Y).type && (X).val + 1 == (Y).val)
#define succ2(St, X, Y) ((X).type == (Y).type && (X).val + 2 == (Y).val)
#define succ3(St, X, Y) ((X).type == (Y).type && (X).val + 3 == (Y).val)

#ifdef NO_FPE_SIGNALS 
#define no_fpe_signals(St) 1
#else
#define no_fpe_signals(St) 0
#endif

/*
 * Predicate that tests whether a jump table can be used.
 */

static int
use_jump_tab(LoaderState* stp, GenOpArg Size, GenOpArg* Rest)
{
    Sint min, max;
    Sint i;

    if (Size.val < 2 || Size.val % 2 != 0) {
	return 0;
    }

    /* we may be called with sequences of tagged fixnums or atoms;
       return early in latter case, before we access the values */
    if (Rest[0].type != TAG_i || Rest[1].type != TAG_f)
	return 0;
    min = max = Rest[0].val;
    for (i = 2; i < Size.val; i += 2) {
	if (Rest[i].type != TAG_i || Rest[i+1].type != TAG_f) {
	    return 0;
	}
	if (Rest[i].val < min) {
	    min = Rest[i].val;
	} else if (max < Rest[i].val) {
	    max = Rest[i].val;
	}
    }

    return max - min <= Size.val;
}

/*
 * Predicate to test whether all values in a table are big numbers.
 */

static int
all_values_are_big(LoaderState* stp, GenOpArg Size, GenOpArg* Rest)
{
    int i;

    if (Size.val < 2 || Size.val % 2 != 0) {
	return 0;
    }

    for (i = 0; i < Size.val; i += 2) {
	if (Rest[i].type != TAG_q) {
	    return 0;
	}
	if (is_not_big(stp->literals[Rest[i].val].term)) {
	    return 0;
	}
	if (Rest[i+1].type != TAG_f) {
	    return 0;
	}
    }

    return 1;
}


/*
 * Predicate to test whether all values in a table have a fixed size.
 */

static int
fixed_size_values(LoaderState* stp, GenOpArg Size, GenOpArg* Rest)
{
    int i;

    if (Size.val < 2 || Size.val % 2 != 0) {
	return 0;
    }

    for (i = 0; i < Size.val; i += 2) {
	if (Rest[i+1].type != TAG_f)
	    return 0;
	switch (Rest[i].type) {
	case TAG_a:
	case TAG_i:
	case TAG_v:
	    break;
	case TAG_q:
	    return is_float(stp->literals[Rest[i].val].term);
	default:
	    return 0;
	}
    }

    return 1;
}

static int
mixed_types(LoaderState* stp, GenOpArg Size, GenOpArg* Rest)
{
    int i;
    Uint type;

    if (Size.val < 2 || Size.val % 2 != 0) {
	return 0;
    }

    type = Rest[0].type;
    for (i = 0; i < Size.val; i += 2) {
	if (Rest[i].type != type)
	    return 1;
    }

    return 0;
}

/*
 * Generate an instruction for element/2.
 */

static GenOp*
gen_element(LoaderState* stp, GenOpArg Fail, GenOpArg Index,
		      GenOpArg Tuple, GenOpArg Dst)
{
    GenOp* op;

    NEW_GENOP(stp, op);
    op->op = genop_i_element_4;
    op->arity = 4;
    op->a[0] = Fail;
    op->a[1] = Index;
    op->a[2] = Tuple;
    op->a[3] = Dst;
    op->next = NULL;

    /*
     * If safe, generate a faster instruction.
     */

    if (Index.type == TAG_i && Index.val > 0 &&
	(Tuple.type == TAG_r || Tuple.type == TAG_x || Tuple.type == TAG_y)) {
	op->op = genop_i_fast_element_4;
	op->a[1].type = TAG_u;
	op->a[1].val = Index.val;
    }

    return op;
}

static GenOp*
gen_bs_save(LoaderState* stp, GenOpArg Reg, GenOpArg Index)
{
    GenOp* op;

    NEW_GENOP(stp, op);
    op->op = genop_i_bs_save2_2;
    op->arity = 2;
    op->a[0] = Reg;
    op->a[1] = Index;
    if (Index.type == TAG_u) {
	op->a[1].val = Index.val+1;
    } else if (Index.type == TAG_a && Index.val == am_start) {
	op->a[1].type = TAG_u;
	op->a[1].val = 0;
    }
    op->next = NULL;
    return op;
}

static GenOp*
gen_bs_restore(LoaderState* stp, GenOpArg Reg, GenOpArg Index)
{
    GenOp* op;

    NEW_GENOP(stp, op);
    op->op = genop_i_bs_restore2_2;
    op->arity = 2;
    op->a[0] = Reg;
    op->a[1] = Index;
    if (Index.type == TAG_u) {
	op->a[1].val = Index.val+1;
    } else if (Index.type == TAG_a && Index.val == am_start) {
	op->a[1].type = TAG_u;
	op->a[1].val = 0;
    }
    op->next = NULL;
    return op;
}

/*
 * Generate the fastest instruction to fetch an integer from a binary.
 */

static GenOp*
gen_get_integer2(LoaderState* stp, GenOpArg Fail, GenOpArg Ms, GenOpArg Live,
		 GenOpArg Size, GenOpArg Unit,
		 GenOpArg Flags, GenOpArg Dst)
{
    GenOp* op;
    UWord bits;

    NEW_GENOP(stp, op);

    NATIVE_ENDIAN(Flags);
    if (Size.type == TAG_i) {
	if (!safe_mul(Size.val, Unit.val, &bits)) {
	    goto error;
	} else if ((Flags.val & BSF_SIGNED) != 0) {
	    goto generic;
	} else if (bits == 8) {
	    op->op = genop_i_bs_get_integer_8_3;
	    op->arity = 3;
	    op->a[0] = Ms;
	    op->a[1] = Fail;
	    op->a[2] = Dst;
	} else if (bits == 16 && (Flags.val & BSF_LITTLE) == 0) {
	    op->op = genop_i_bs_get_integer_16_3;
	    op->arity = 3;
	    op->a[0] = Ms;
	    op->a[1] = Fail;
	    op->a[2] = Dst;
	} else if (bits == 32 && (Flags.val & BSF_LITTLE) == 0) {
	    op->op = genop_i_bs_get_integer_32_4;
	    op->arity = 4;
	    op->a[0] = Ms;
	    op->a[1] = Fail;
	    op->a[2] = Live;
	    op->a[3] = Dst;
	} else {
	generic:
	    if (bits < SMALL_BITS) {
		op->op = genop_i_bs_get_integer_small_imm_5;
		op->arity = 5;
		op->a[0] = Ms;
		op->a[1].type = TAG_u;
		op->a[1].val = bits;
		op->a[2] = Fail;
		op->a[3] = Flags;
		op->a[4] = Dst;
	    } else {
		op->op = genop_i_bs_get_integer_imm_6;
		op->arity = 6;
		op->a[0] = Ms;
		op->a[1].type = TAG_u;
		op->a[1].val = bits;
		op->a[2] = Live;
		op->a[3] = Fail;
		op->a[4] = Flags;
		op->a[5] = Dst;
	    }
	}
    } else if (Size.type == TAG_q) {
	Eterm big = stp->literals[Size.val].term;
	Uint bigval;

	if (!term_to_Uint(big, &bigval)) {
	error:
	    op->op = genop_jump_1;
	    op->arity = 1;
	    op->a[0] = Fail;
	} else {
	    if (!safe_mul(bigval, Unit.val, &bits)) {
		goto error;
	    }
	    goto generic;
	}
    } else {
	GenOp* op2;
	NEW_GENOP(stp, op2);
	
	op->op = genop_i_fetch_2;
	op->arity = 2;
	op->a[0] = Ms;
	op->a[1] = Size;
	op->next = op2;

	op2->op = genop_i_bs_get_integer_4;
	op2->arity = 4;
	op2->a[0] = Fail;
	op2->a[1] = Live;
	op2->a[2].type = TAG_u;
	op2->a[2].val = (Unit.val << 3) | Flags.val;
	op2->a[3] = Dst;
	op2->next = NULL;
	return op;
    }
    op->next = NULL;
    return op;
}

/*
 * Generate the fastest instruction to fetch a binary from a binary.
 */

static GenOp*
gen_get_binary2(LoaderState* stp, GenOpArg Fail, GenOpArg Ms, GenOpArg Live,
		GenOpArg Size, GenOpArg Unit,
		GenOpArg Flags, GenOpArg Dst)
{
    GenOp* op;
    NEW_GENOP(stp, op);

    NATIVE_ENDIAN(Flags);
    if (Size.type == TAG_a && Size.val == am_all) {
	if (Ms.type == Dst.type && Ms.val == Dst.val) {
	    op->op = genop_i_bs_get_binary_all_reuse_3;
	    op->arity = 3;
	    op->a[0] = Ms;
	    op->a[1] = Fail;
	    op->a[2] = Unit;
	} else {
	    op->op = genop_i_bs_get_binary_all2_5;
	    op->arity = 5;
	    op->a[0] = Fail;
	    op->a[1] = Ms;
	    op->a[2] = Live;	
	    op->a[3] = Unit;
	    op->a[4] = Dst;
	}
    } else if (Size.type == TAG_i) {
	op->op = genop_i_bs_get_binary_imm2_6;
	op->arity = 6;
	op->a[0] = Fail;
	op->a[1] = Ms;
	op->a[2] = Live;
	op->a[3].type = TAG_u;
	if (!safe_mul(Size.val, Unit.val, &op->a[3].val)) {
	    goto error;
	}
	op->a[4] = Flags;
	op->a[5] = Dst;
    } else if (Size.type == TAG_q) {
	Eterm big = stp->literals[Size.val].term;
	Uint bigval;

	if (!term_to_Uint(big, &bigval)) {
	error:
	    op->op = genop_jump_1;
	    op->arity = 1;
	    op->a[0] = Fail;
	} else {
	    op->op = genop_i_bs_get_binary_imm2_6;
	    op->arity = 6;
	    op->a[0] = Fail;
	    op->a[1] = Ms;
	    op->a[2] = Live;
	    op->a[3].type = TAG_u;
	    if (!safe_mul(bigval, Unit.val, &op->a[3].val)) {
		goto error;
	    }
	    op->a[4] = Flags;
	    op->a[5] = Dst;
	}
    } else {
	op->op = genop_i_bs_get_binary2_6;
	op->arity = 6;
	op->a[0] = Fail;
	op->a[1] = Ms;
	op->a[2] = Live;
	op->a[3] = Size;
	op->a[4].type = TAG_u;
	op->a[4].val = (Unit.val << 3) | Flags.val;
	op->a[5] = Dst;
    }
    op->next = NULL;
    return op;
}

/*
 * Predicate to test whether a heap binary should be generated.
 */

static int
should_gen_heap_bin(LoaderState* stp, GenOpArg Src)
{
    return Src.val <= ERL_ONHEAP_BIN_LIMIT;
}

/*
 * Predicate to test whether a binary construction is too big.
 */

static int
binary_too_big(LoaderState* stp, GenOpArg Size)
{
    return Size.type == TAG_u && ((Size.val >> (8*sizeof(Uint)-3)) != 0);
}

static int
binary_too_big_bits(LoaderState* stp, GenOpArg Size)
{
    return Size.type == TAG_u && (((Size.val+7)/8) >> (8*sizeof(Uint)-3) != 0);
}

#define new_float_allocation(Stp) ((Stp)->new_float_instructions)

static GenOp*
gen_put_binary(LoaderState* stp, GenOpArg Fail,GenOpArg Size,
	       GenOpArg Unit, GenOpArg Flags, GenOpArg Src)
{
    GenOp* op;
    NEW_GENOP(stp, op);

    NATIVE_ENDIAN(Flags);
    if (Size.type == TAG_a && Size.val == am_all) {
	op->op = genop_i_new_bs_put_binary_all_3;
	op->arity = 3;
	op->a[0] = Fail;
	op->a[1] = Src;
	op->a[2] = Unit;
    } else if (Size.type == TAG_i) {
	op->op = genop_i_new_bs_put_binary_imm_3;
	op->arity = 3;
	op->a[0] = Fail;
	op->a[1].type = TAG_u;
	if (safe_mul(Size.val, Unit.val, &op->a[1].val)) {
	    op->a[2] = Src;
	} else {
	    op->op = genop_badarg_1;
	    op->arity = 1;
	    op->a[0] = Fail;
	}
    } else {
	op->op = genop_i_new_bs_put_binary_4;
	op->arity = 4;
	op->a[0] = Fail;
	op->a[1] = Size;
	op->a[2].type = TAG_u;
	op->a[2].val = (Unit.val << 3) | (Flags.val & 7);
	op->a[3] = Src;
    }

    op->next = NULL;
    return op;
}

static GenOp*
gen_put_integer(LoaderState* stp, GenOpArg Fail, GenOpArg Size,
		GenOpArg Unit, GenOpArg Flags, GenOpArg Src)
{
    GenOp* op;
    NEW_GENOP(stp, op);

    NATIVE_ENDIAN(Flags);
    if (Size.type == TAG_i && Size.val < 0) {
    error:
	/* Negative size must fail */
	op->op = genop_badarg_1;
	op->arity = 1;
	op->a[0] = Fail;
    } else if (Size.type == TAG_i) {
	op->op = genop_i_new_bs_put_integer_imm_4;
	op->arity = 4;
	op->a[0] = Fail;
	op->a[1].type = TAG_u;
	if (!safe_mul(Size.val, Unit.val, &op->a[1].val)) {
	    goto error;
	}
	op->a[1].val = Size.val * Unit.val;
	op->a[2].type = Flags.type;
	op->a[2].val = (Flags.val & 7);
	op->a[3] = Src;
    } else if (Size.type == TAG_q) {
	Eterm big = stp->literals[Size.val].term;
	Uint bigval;

	if (!term_to_Uint(big, &bigval)) {
	    goto error;
	} else {
	    op->op = genop_i_new_bs_put_integer_imm_4;
	    op->arity = 4;
	    op->a[0] = Fail;
	    op->a[1].type = TAG_u;
	    op->a[1].val = bigval * Unit.val;
	    op->a[2].type = Flags.type;
	    op->a[2].val = (Flags.val & 7);
	    op->a[3] = Src;
	}
    } else {
	op->op = genop_i_new_bs_put_integer_4;
	op->arity = 4;
	op->a[0] = Fail;
	op->a[1] = Size;
	op->a[2].type = TAG_u;
	op->a[2].val = (Unit.val << 3) | (Flags.val & 7);
	op->a[3] = Src;
    }
    op->next = NULL;
    return op;
}

static GenOp*
gen_put_float(LoaderState* stp, GenOpArg Fail, GenOpArg Size,
	      GenOpArg Unit, GenOpArg Flags, GenOpArg Src)
{
    GenOp* op;
    NEW_GENOP(stp, op);

    NATIVE_ENDIAN(Flags);
    if (Size.type == TAG_i) {
	op->op = genop_i_new_bs_put_float_imm_4;
	op->arity = 4;
	op->a[0] = Fail;
	op->a[1].type = TAG_u;
	if (!safe_mul(Size.val, Unit.val, &op->a[1].val)) {
	    op->op = genop_badarg_1;
	    op->arity = 1;
	    op->a[0] = Fail;
	} else {
	    op->a[2] = Flags;
	    op->a[3] = Src;
	}
    } else {
	op->op = genop_i_new_bs_put_float_4;
	op->arity = 4;
	op->a[0] = Fail;
	op->a[1] = Size;
	op->a[2].type = TAG_u;
	op->a[2].val = (Unit.val << 3) | (Flags.val & 7);
	op->a[3] = Src;
    }
    op->next = NULL;
    return op;
}

/*
 * Generate an instruction to fetch a float from a binary.
 */

static GenOp*
gen_get_float2(LoaderState* stp, GenOpArg Fail, GenOpArg Ms, GenOpArg Live,
		GenOpArg Size, GenOpArg Unit, GenOpArg Flags, GenOpArg Dst)
{
    GenOp* op;
    NEW_GENOP(stp, op);

    NATIVE_ENDIAN(Flags);
    op->op = genop_i_bs_get_float2_6;
    op->arity = 6;
    op->a[0] = Fail;
    op->a[1] = Ms;
    op->a[2] = Live;
    op->a[3] = Size;
    op->a[4].type = TAG_u;
    op->a[4].val = (Unit.val << 3) | Flags.val;
    op->a[5] = Dst;
    op->next = NULL;
    return op;
}

/*
 * Generate the fastest instruction for bs_skip_bits.
 */

static GenOp*
gen_skip_bits2(LoaderState* stp, GenOpArg Fail, GenOpArg Ms, 
	       GenOpArg Size, GenOpArg Unit, GenOpArg Flags)
{
    GenOp* op;

    NATIVE_ENDIAN(Flags);
    NEW_GENOP(stp, op);
    if (Size.type == TAG_a && Size.val == am_all) {
	op->op = genop_i_bs_skip_bits_all2_3;
	op->arity = 3;
	op->a[0] = Fail;
	op->a[1] = Ms; 
	op->a[2] = Unit;
    } else if (Size.type == TAG_i) {
	op->op = genop_i_bs_skip_bits_imm2_3;
	op->arity = 3;
	op->a[0] = Fail;
	op->a[1] = Ms; 
	op->a[2].type = TAG_u;
	if (!safe_mul(Size.val, Unit.val, &op->a[2].val)) {
	    goto error;
	}
    } else if (Size.type == TAG_q) {
	Eterm big = stp->literals[Size.val].term;
	Uint bigval;

	if (!term_to_Uint(big, &bigval)) {
	error:
	    op->op = genop_jump_1;
	    op->arity = 1;
	    op->a[0] = Fail;
	} else {
	    op->op = genop_i_bs_skip_bits_imm2_3;
	    op->arity = 3;
	    op->a[0] = Fail;
	    op->a[1] = Ms; 
	    op->a[2].type = TAG_u;
	    if (!safe_mul(bigval, Unit.val, &op->a[2].val)) {
		goto error;
	    }
	}
    } else {
	op->op = genop_i_bs_skip_bits2_4;
	op->arity = 4;
	op->a[0] = Fail;
	op->a[1] = Ms; 
	op->a[2] = Size;
	op->a[3] = Unit;
    }
    op->next = NULL;
    return op;
}

static int
smp(LoaderState* stp)
{
#ifdef ERTS_SMP
    return 1;
#else
    return 0;
#endif
}

/*
 * Mark this label.
 */
static int
smp_mark_target_label(LoaderState* stp, GenOpArg L)
{
#ifdef ERTS_SMP
    ASSERT(L.type == TAG_f);
    stp->labels[L.val].looprec_targeted = 1;
#endif
    return 1;
}

/*
 * Test whether this label was targeted by a loop_rec/2 instruction.
 */

static int
smp_already_locked(LoaderState* stp, GenOpArg L)
{
#ifdef ERTS_SMP
    ASSERT(L.type == TAG_u);
    return stp->labels[L.val].looprec_targeted;
#else
    return 0;
#endif
}

/*
 * Generate a timeout instruction for a literal timeout.
 */

static GenOp*
gen_literal_timeout(LoaderState* stp, GenOpArg Fail, GenOpArg Time)
{
    GenOp* op;
    Sint timeout;

    NEW_GENOP(stp, op);
    op->op = genop_i_wait_timeout_2;
    op->next = NULL;
    op->arity = 2;
    op->a[0] = Fail;
    op->a[1].type = TAG_u;
    
    if (Time.type == TAG_i && (timeout = Time.val) >= 0 &&
#if defined(ARCH_64) && !HALFWORD_HEAP
	(timeout >> 32) == 0
#else
	1
#endif
	) {
	op->a[1].val = timeout;
#if !defined(ARCH_64) || HALFWORD_HEAP
    } else if (Time.type == TAG_q) {
	Eterm big;

	big = stp->literals[Time.val].term;
	if (is_not_big(big)) {
	    goto error;
	}
	if (big_arity(big) > 1 || big_sign(big)) {
	    goto error;
	} else {
	    Uint u;
	    (void) term_to_Uint(big, &u);
	    op->a[1].val = (BeamInstr) u;
	}
#endif
    } else {
#if !defined(ARCH_64) || HALFWORD_HEAP
    error:
#endif
	op->op = genop_i_wait_error_0;
	op->arity = 0;
    }
    return op;
}

static GenOp*
gen_literal_timeout_locked(LoaderState* stp, GenOpArg Fail, GenOpArg Time)
{
    GenOp* op;
    Sint timeout;

    NEW_GENOP(stp, op);
    op->op = genop_i_wait_timeout_locked_2;
    op->next = NULL;
    op->arity = 2;
    op->a[0] = Fail;
    op->a[1].type = TAG_u;
    
    if (Time.type == TAG_i && (timeout = Time.val) >= 0 &&
#if defined(ARCH_64) && !HALFWORD_HEAP
	(timeout >> 32) == 0
#else
	1
#endif
	) {
	op->a[1].val = timeout;
#if !defined(ARCH_64) || HALFWORD_HEAP
    } else if (Time.type == TAG_q) {
	Eterm big;

	big = stp->literals[Time.val].term;
	if (is_not_big(big)) {
	    goto error;
	}
	if (big_arity(big) > 1 || big_sign(big)) {
	    goto error;
	} else {
	    Uint u;
	    (void) term_to_Uint(big, &u);
	    op->a[1].val = (BeamInstr) u;
	}
#endif
    } else {
#if !defined(ARCH_64) || HALFWORD_HEAP
    error:
#endif
	op->op = genop_i_wait_error_locked_0;
	op->arity = 0;
    }
    return op;
}

/*
 * Tag the list of values with tuple arity tags.
 */

static GenOp*
gen_select_tuple_arity(LoaderState* stp, GenOpArg S, GenOpArg Fail,
		       GenOpArg Size, GenOpArg* Rest)

{
    GenOp* op;
    int arity = Size.val + 3;
    int size = Size.val / 2;
    int i;

    /*
     * Verify the validity of the list.
     */

    if (Size.val % 2 != 0)
	return NULL;
    for (i = 0; i < Size.val; i += 2) {
	if (Rest[i].type != TAG_u || Rest[i+1].type != TAG_f) {
	    return NULL;
	}
    }

    /*
     * Generate the generic instruction.
     */

    NEW_GENOP(stp, op);
    op->next = NULL;
    op->op = genop_i_select_tuple_arity_3;
    GENOP_ARITY(op, arity);
    op->a[0] = S;
    op->a[1] = Fail;
    op->a[2].type = TAG_u;
    op->a[2].val = Size.val / 2;
    for (i = 0; i < Size.val; i += 2) {
	op->a[i+3].type = TAG_v;
	op->a[i+3].val = make_arityval(Rest[i].val);
	op->a[i+4] = Rest[i+1];
    }

    /*
     * Sort the values to make them useful for a binary search.
     */

    qsort(op->a+3, size, 2*sizeof(GenOpArg), 
	   (int (*)(const void *, const void *)) genopargcompare);
#ifdef DEBUG
    for (i = 3; i < arity-2; i += 2) {
	ASSERT(op->a[i].val < op->a[i+2].val);
    }
#endif
    return op;
}

/*
 * Split a list consisting of both small and bignumbers into two
 * select_val instructions.
 */

static GenOp*
gen_split_values(LoaderState* stp, GenOpArg S, GenOpArg Fail,
		 GenOpArg Size, GenOpArg* Rest)

{
    GenOp* op1;
    GenOp* op2;
    GenOp* label;
    Uint type;
    int i;

    ASSERT(Size.val >= 2 && Size.val % 2 == 0);

    NEW_GENOP(stp, label);
    label->op = genop_label_1;
    label->arity = 1;
    label->a[0].type = TAG_u;
    label->a[0].val = new_label(stp);

    NEW_GENOP(stp, op1);
    op1->op = genop_select_val_3;
    GENOP_ARITY(op1, 3 + Size.val);
    op1->arity = 3;
    op1->a[0] = S;
    op1->a[1].type = TAG_f;
    op1->a[1].val = label->a[0].val;
    op1->a[2].type = TAG_u;
    op1->a[2].val = 0;

    NEW_GENOP(stp, op2);
    op2->op = genop_select_val_3;
    GENOP_ARITY(op2, 3 + Size.val);
    op2->arity = 3;
    op2->a[0] = S;
    op2->a[1] = Fail;
    op2->a[2].type = TAG_u;
    op2->a[2].val = 0;

    op1->next = label;
    label->next = op2;
    op2->next = NULL;

    type = Rest[0].type;

    ASSERT(Size.type == TAG_u);
    for (i = 0; i < Size.val; i += 2) {
	GenOp* op = (Rest[i].type == type) ? op1 : op2;
	int dst = 3 + op->a[2].val;

	ASSERT(Rest[i+1].type == TAG_f);
	op->a[dst] = Rest[i];
	op->a[dst+1] = Rest[i+1];
	op->arity += 2;
	op->a[2].val += 2;
    }

    /*
     * None of the instructions should have zero elements in the list.
     */

    ASSERT(op1->a[2].val > 0);
    ASSERT(op2->a[2].val > 0);

    return op1;
}

/*
 * Generate a jump table.
 */

static GenOp*
gen_jump_tab(LoaderState* stp, GenOpArg S, GenOpArg Fail, GenOpArg Size, GenOpArg* Rest)
{
    Sint min, max;
    Sint i;
    Sint size;
    Sint arity;
    int fixed_args;
    GenOp* op;

    ASSERT(Size.val >= 2 && Size.val % 2 == 0);

    /*
     * Calculate the minimum and maximum values and size of jump table.
     */

    ASSERT(Rest[0].type == TAG_i);
    min = max = Rest[0].val;
    for (i = 2; i < Size.val; i += 2) {
	ASSERT(Rest[i].type == TAG_i && Rest[i+1].type == TAG_f);
	if (Rest[i].val < min) {
	    min = Rest[i].val;
	} else if (max < Rest[i].val) {
	    max = Rest[i].val;
	}
    }
    size = max - min + 1;


    /*
     * Allocate structure and fill in the fixed fields.
     */

    NEW_GENOP(stp, op);
    op->next = NULL;
    if (min == 0) {
	op->op = genop_i_jump_on_val_zero_3;
	fixed_args = 3;
    } else {
	op->op = genop_i_jump_on_val_4;
	fixed_args = 4;
    }
    arity = fixed_args + size;
    GENOP_ARITY(op, arity);
    op->a[0] = S;
    op->a[1] = Fail;
    op->a[2].type = TAG_u;
    op->a[2].val = size;
    op->a[3].type = TAG_u;
    op->a[3].val = min;


    /*
     * Fill in the jump table.
     */

    for (i = fixed_args; i < arity; i++) {
	op->a[i] = Fail;
    }
    for (i = 0; i < Size.val; i += 2) {
	int index;
	index = fixed_args+Rest[i].val-min;
	ASSERT(fixed_args <= index && index < arity);
	op->a[index] = Rest[i+1];
    }
    return op;
}

/* 
 *  Compare function for qsort().
 */

static int
genopargcompare(GenOpArg* a, GenOpArg* b)
{
    if (a->val < b->val)
	return -1;
    else if (a->val == b->val)
	return 0;
    else
	return 1;
}

/*
 * Generate a select_val instruction.  We know that a jump table is not suitable,
 * and that all values are of the same type (integer, atoms, floats; never bignums).
 */

static GenOp*
gen_select_val(LoaderState* stp, GenOpArg S, GenOpArg Fail,
	       GenOpArg Size, GenOpArg* Rest)
{
    GenOp* op;
    int arity = Size.val + 3;
    int size = Size.val / 2;
    int i;

    NEW_GENOP(stp, op);
    op->next = NULL;
    if (Rest[0].type != TAG_q) {
	op->op = genop_i_select_val_3;
    } else {
	ASSERT(is_float(stp->literals[Rest[0].val].term));
	op->op = genop_i_select_float_3;
    }
    GENOP_ARITY(op, arity);
    op->a[0] = S;
    op->a[1] = Fail;
    op->a[2].type = TAG_u;
    op->a[2].val = size;
    for (i = 3; i < arity; i++) {
	op->a[i] = Rest[i-3];
    }

    /*
     * Sort the values to make them useful for a binary search.
     */

    qsort(op->a+3, size, 2*sizeof(GenOpArg), 
	  (int (*)(const void *, const void *)) genopargcompare);
#ifdef DEBUG
    for (i = 3; i < arity-2; i += 2) {
	ASSERT(op->a[i].val < op->a[i+2].val);
    }
#endif

    return op;
}

/* 
 *  Compare function for qsort().
 */

static int
genbigcompare(GenOpArg* a, GenOpArg* b)
{
    int val = (int)(b->bigarity - a->bigarity);
    
    return val != 0 ? val : ((int) (a->val - b->val));
}

/*
 * Generate a select_val instruction for big numbers.
 */

static GenOp*
gen_select_big(LoaderState* stp, GenOpArg S, GenOpArg Fail,
	       GenOpArg Size, GenOpArg* Rest)
{
    GenOp* op;
    int arity = Size.val + 2 + 1;
    int size = Size.val / 2;
    int i;

    NEW_GENOP(stp, op);
    op->next = NULL;
    op->op = genop_i_select_big_2;
    GENOP_ARITY(op, arity);
    op->a[0] = S;
    op->a[1] = Fail;
    for (i = 0; i < Size.val; i += 2) {
	ASSERT(Rest[i].type == TAG_q);
	op->a[i+2] = Rest[i];
	op->a[i+2].bigarity = *big_val(stp->literals[op->a[i+2].val].term);
	op->a[i+3] = Rest[i+1];
    }
    ASSERT(i+2 == arity-1);
    op->a[arity-1].type = TAG_u;
    op->a[arity-1].val = 0;

    /*
     * Sort the values in descending arity order.
     */

    qsort(op->a+2, size, 2*sizeof(GenOpArg), 
	  (int (*)(const void *, const void *)) genbigcompare);

    return op;
}


/*
 * Replace a select_val instruction with a constant controlling expression
 * with a jump instruction.
 */

static GenOp*
const_select_val(LoaderState* stp, GenOpArg S, GenOpArg Fail,
		 GenOpArg Size, GenOpArg* Rest)
{
    GenOp* op;
    int i;

    ASSERT(Size.type == TAG_u);
    ASSERT(S.type == TAG_q);

    NEW_GENOP(stp, op);
    op->next = NULL;
    op->op = genop_jump_1;
    op->arity = 1;

    /*
     * Search for a literal matching the controlling expression.
     */

    if (S.type == TAG_q) {
	Eterm expr = stp->literals[S.val].term;
	for (i = 0; i < Size.val; i += 2) {
	    if (Rest[i].type == TAG_q) {
		Eterm term = stp->literals[Rest[i].val].term;
		if (eq(term, expr)) {
		    ASSERT(Rest[i+1].type == TAG_f);
		    op->a[0] = Rest[i+1];
		    return op;
		}
	    }
	}
    }

    /*
     * No match.  Use the failure label.
     */

    op->a[0] = Fail;
    return op;
}


static GenOp*
gen_func_info(LoaderState* stp, GenOpArg mod, GenOpArg func,
	      GenOpArg arity, GenOpArg label)
{
    GenOp* fi;
    GenOp* op;

    NEW_GENOP(stp, fi);
    fi->op = genop_i_func_info_4;
    fi->arity = 4;
    fi->a[0].type = TAG_u;	/* untagged Zero */
    fi->a[0].val = 0;
    fi->a[1] = mod;
    fi->a[2] = func;
    fi->a[3] = arity;

    NEW_GENOP(stp, op);
    op->op = genop_label_1;
    op->arity = 1;
    op->a[0] = label;
    
    fi->next = op;
    op->next = NULL;

    return fi;
}



static GenOp*
gen_make_fun2(LoaderState* stp, GenOpArg idx)
{
    ErlFunEntry* fe;
    GenOp* op;

    if (idx.val >= stp->num_lambdas) {
	stp->lambda_error = "missing or short chunk 'FunT'";
	fe = 0;
    } else {
	fe = stp->lambdas[idx.val].fe;
    }

    NEW_GENOP(stp, op);
    op->op = genop_i_make_fun_2;
    op->arity = 2;
    op->a[0].type = TAG_u;
    op->a[0].val = (BeamInstr) fe;
    op->a[1].type = TAG_u;
    op->a[1].val = stp->lambdas[idx.val].num_free;
    op->next = NULL;
    return op;
}
/*
 * Rewrite gc_bifs with one parameter (the common case). Utilized
 * in ops.tab to rewrite instructions calling bif's in guards
 * to use a garbage collecting implementation. The instructions
 * are sometimes once again rewritten to handle literals (putting the
 * parameter in the mostly unused r[0] before the instruction is executed).
 */
static GenOp*
gen_guard_bif1(LoaderState* stp, GenOpArg Fail, GenOpArg Live, GenOpArg Bif,
	      GenOpArg Src, GenOpArg Dst)
{
    GenOp* op;
    BifFunction bf;

    NEW_GENOP(stp, op);
    op->op = genop_i_gc_bif1_5;
    op->arity = 5;
    op->a[0] = Fail;
    op->a[1].type = TAG_u;
    bf = stp->import[Bif.val].bf;
    /* The translations here need to have a reverse counterpart in
       beam_emu.c:translate_gc_bif for error handling to work properly. */
    if (bf == length_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_length_1;
    } else if (bf == size_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_size_1;
    } else if (bf == bit_size_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_bit_size_1;
    } else if (bf == byte_size_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_byte_size_1;
    } else if (bf == abs_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_abs_1;
    } else if (bf == float_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_float_1;
    } else if (bf == round_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_round_1;
    } else if (bf == trunc_1) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_trunc_1;
    } else {
	abort();
    }
    op->a[2] = Src;
    op->a[3] = Live;
    op->a[4] = Dst;
    op->next = NULL;
    return op;
}

/*
 * This is used by the ops.tab rule that rewrites gc_bifs with two parameters
 * The instruction returned is then again rewritten to an i_load instruction
 * folowed by i_gc_bif2_jIId, to handle literals properly.
 * As opposed to the i_gc_bif1_jIsId, the instruction  i_gc_bif2_jIId is
 * always rewritten, regardless of if there actually are any literals.
 */
static GenOp*
gen_guard_bif2(LoaderState* stp, GenOpArg Fail, GenOpArg Live, GenOpArg Bif,
	      GenOpArg S1, GenOpArg S2, GenOpArg Dst)
{
    GenOp* op;
    BifFunction bf;

    NEW_GENOP(stp, op);
    op->op = genop_ii_gc_bif2_6;
    op->arity = 6;
    op->a[0] = Fail;
    op->a[1].type = TAG_u;
    bf = stp->import[Bif.val].bf;
    /* The translations here need to have a reverse counterpart in
       beam_emu.c:translate_gc_bif for error handling to work properly. */
    if (bf == binary_part_2) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_binary_part_2;
    } else {
	abort();
    }
    op->a[2] = S1;
    op->a[3] = S2;
    op->a[4] = Live;
    op->a[5] = Dst;
    op->next = NULL;
    return op;
}

/*
 * This is used by the ops.tab rule that rewrites gc_bifs with three parameters
 * The instruction returned is then again rewritten to a move instruction that
 * uses r[0] for temp storage, followed by an i_load instruction,
 * folowed by i_gc_bif3_jIsId, to handle literals properly. Rewriting
 * always occur, as with the gc_bif2 counterpart.
 */
static GenOp*
gen_guard_bif3(LoaderState* stp, GenOpArg Fail, GenOpArg Live, GenOpArg Bif,
	      GenOpArg S1, GenOpArg S2, GenOpArg S3, GenOpArg Dst)
{
    GenOp* op;
    BifFunction bf;

    NEW_GENOP(stp, op);
    op->op = genop_ii_gc_bif3_7;
    op->arity = 7;
    op->a[0] = Fail;
    op->a[1].type = TAG_u;
    bf = stp->import[Bif.val].bf;
    /* The translations here need to have a reverse counterpart in
       beam_emu.c:translate_gc_bif for error handling to work properly. */
    if (bf == binary_part_3) {
	op->a[1].val = (BeamInstr) (void *) erts_gc_binary_part_3;
    } else {
	abort();
    }
    op->a[2] = S1;
    op->a[3] = S2;
    op->a[4] = S3;
    op->a[5] = Live;
    op->a[6] = Dst;
    op->next = NULL;
    return op;
}


/*
 * Freeze the code in memory, move the string table into place,
 * resolve all labels.
 */

static int
freeze_code(LoaderState* stp)
{
    BeamInstr* code = stp->code;
    Uint *literal_end = NULL;
    Uint index;
    int i;
    byte* str_table;
    unsigned strtab_size = stp->chunks[STR_CHUNK].size;
    unsigned attr_size = stp->chunks[ATTR_CHUNK].size;
    unsigned compile_size = stp->chunks[COMPILE_CHUNK].size;
    Uint size;
    unsigned catches;
    Sint decoded_size;

    /*
     * Verify that there was a correct 'FunT' chunk if there were
     * make_fun2 instructions in the file.
     */

    if (stp->lambda_error != NULL) {
	LoadError0(stp, stp->lambda_error);
    }

    
    /*
     * Calculate the final size of the code.
     */

    size = (stp->ci * sizeof(BeamInstr)) + (stp->total_literal_size * sizeof(Eterm)) +
	strtab_size + attr_size + compile_size;

    /*
     * Move the code to its final location.
     */

    code = (BeamInstr *) erts_realloc(ERTS_ALC_T_CODE, (void *) code, size);
    CHKBLK(ERTS_ALC_T_CODE,code);
    /*
     * Place a pointer to the op_int_code_end instruction in the
     * function table in the beginning of the file.
     */

    code[MI_FUNCTIONS+stp->num_functions] = (BeamInstr) (code + stp->ci - 1);
    CHKBLK(ERTS_ALC_T_CODE,code);

    /*
     * Store the pointer to the on_load function.
     */

    if (stp->on_load) {
	code[MI_ON_LOAD_FUNCTION_PTR] = (BeamInstr) (code + stp->on_load);
    } else {
	code[MI_ON_LOAD_FUNCTION_PTR] = 0;
    }
    CHKBLK(ERTS_ALC_T_CODE,code);

    literal_end = (Uint *) (code+stp->ci);
    /*
     * Place the literal heap directly after the code and fix up all
     * instructions that refer to it.
     */
    {
	Uint* ptr;
	Uint* low;
	Uint* high;
	LiteralPatch* lp;

	low = (Uint *) (code+stp->ci);
	high = low + stp->total_literal_size;
	code[MI_LITERALS_START] = (BeamInstr) low;
	code[MI_LITERALS_END] = (BeamInstr) high;
	ptr = low;
	for (i = 0; i < stp->num_literals; i++) {
	    Uint offset;

	    sys_memcpy(ptr, stp->literals[i].heap,
		       stp->literals[i].heap_size*sizeof(Eterm));
	    offset = ptr - stp->literals[i].heap;
	    stp->literals[i].offset = offset;
	    high = ptr + stp->literals[i].heap_size;
	    while (ptr < high) {
		Eterm val = *ptr;
		switch (primary_tag(val)) {
		case TAG_PRIMARY_LIST:
		case TAG_PRIMARY_BOXED:
		    *ptr++ = offset_ptr(val, offset);
		    break;
		case TAG_PRIMARY_HEADER:
		    ptr++;
		    if (header_is_thing(val)) {
			ptr += thing_arityval(val);
		    }
		    break;
		default:
		    ptr++;
		    break;
		}
	    }
	    ASSERT(ptr == high);
	}
	lp = stp->literal_patches;
	while (lp != 0) {
	    BeamInstr* op_ptr;
	    Uint literal;
	    Literal* lit;

	    op_ptr = code + lp->pos;
	    lit = &stp->literals[op_ptr[0]];
	    literal = lit->term;
	    if (is_boxed(literal) || is_list(literal)) {
		literal = offset_ptr(literal, lit->offset);
	    }
	    op_ptr[0] = literal;
	    lp = lp->next;
	}
	literal_end += stp->total_literal_size;
    }
    
    /*
     * Place the string table and, optionally, attributes, after the literal heap.
     */
    CHKBLK(ERTS_ALC_T_CODE,code);

    sys_memcpy(literal_end, stp->chunks[STR_CHUNK].start, strtab_size);
    CHKBLK(ERTS_ALC_T_CODE,code);
    str_table = (byte *) literal_end;
    if (attr_size) {
	byte* attr = str_table + strtab_size;
	sys_memcpy(attr, stp->chunks[ATTR_CHUNK].start, stp->chunks[ATTR_CHUNK].size);
	code[MI_ATTR_PTR] = (BeamInstr) attr;
	code[MI_ATTR_SIZE] = (BeamInstr) stp->chunks[ATTR_CHUNK].size;
	decoded_size = erts_decode_ext_size(attr, attr_size, 0);
	if (decoded_size < 0) {
 	    LoadError0(stp, "bad external term representation of module attributes");
 	}
	code[MI_ATTR_SIZE_ON_HEAP] = decoded_size;
    }
    CHKBLK(ERTS_ALC_T_CODE,code);
    if (compile_size) {
	byte* compile_info = str_table + strtab_size + attr_size;
    CHKBLK(ERTS_ALC_T_CODE,code);
	sys_memcpy(compile_info, stp->chunks[COMPILE_CHUNK].start,
	       stp->chunks[COMPILE_CHUNK].size);
    CHKBLK(ERTS_ALC_T_CODE,code);
	code[MI_COMPILE_PTR] = (BeamInstr) compile_info;
    CHKBLK(ERTS_ALC_T_CODE,code);
	code[MI_COMPILE_SIZE] = (BeamInstr) stp->chunks[COMPILE_CHUNK].size;
    CHKBLK(ERTS_ALC_T_CODE,code);
	decoded_size = erts_decode_ext_size(compile_info, compile_size, 0);
    CHKBLK(ERTS_ALC_T_CODE,code);
	if (decoded_size < 0) {
 	    LoadError0(stp, "bad external term representation of compilation information");
 	}
    CHKBLK(ERTS_ALC_T_CODE,code);
	code[MI_COMPILE_SIZE_ON_HEAP] = decoded_size;
    }
    CHKBLK(ERTS_ALC_T_CODE,code);

    /*
     * Go through all i_new_bs_put_strings instructions, restore the pointer to
     * the instruction and convert string offsets to pointers (to the
     * FIRST character).
     */

    index = stp->new_bs_put_strings;
    while (index != 0) {
	Uint next = code[index];
	code[index] = BeamOpCode(op_bs_put_string_II);
	code[index+2] = (BeamInstr) (str_table + code[index+2]);
	index = next;
    }
    CHKBLK(ERTS_ALC_T_CODE,code);

    {
	StringPatch* sp = stp->string_patches;

	while (sp != 0) {
	    BeamInstr* op_ptr;
	    byte* strp;

	    op_ptr = code + sp->pos;
	    strp = str_table + op_ptr[0];
	    op_ptr[0] = (BeamInstr) strp;
	    sp = sp->next;
	}
    }
    CHKBLK(ERTS_ALC_T_CODE,code);

    /*
     * Resolve all labels.
     */

    for (i = 0; i < stp->num_labels; i++) {
	Uint this_patch;
	Uint next_patch;
	Uint value = stp->labels[i].value;
	
	if (value == 0 && stp->labels[i].patches != 0) {
	    LoadError1(stp, "label %d not resolved", i);
	}
	ASSERT(value < stp->ci);
	this_patch = stp->labels[i].patches;
	while (this_patch != 0) {
	    ASSERT(this_patch < stp->ci);
	    next_patch = code[this_patch];
	    ASSERT(next_patch < stp->ci);
	    code[this_patch] = (BeamInstr) (code + value);
	    this_patch = next_patch;
	}
    }
    CHKBLK(ERTS_ALC_T_CODE,code);

    /*
     * Fix all catch_yf instructions.
     */
    index = stp->catches;
    catches = BEAM_CATCHES_NIL;
    while (index != 0) {
	BeamInstr next = code[index];
	code[index] = BeamOpCode(op_catch_yf);
	catches = beam_catches_cons((BeamInstr *)code[index+2], catches);
	code[index+2] = make_catch(catches);
	index = next;
    }
    stp->catches = catches;
    CHKBLK(ERTS_ALC_T_CODE,code);

    /*
     * Save the updated code pointer and code size.
     */

    stp->code = code;
    stp->loaded_size = size;

    CHKBLK(ERTS_ALC_T_CODE,code);
    return 1;

 load_error:
    /*
     * Make sure that the caller frees the newly reallocated block, and
     * not the old one (in case it has moved).
     */
    stp->code = code;
    return 0;
}


static void
final_touch(LoaderState* stp)
{
    int i;
    int on_load = stp->on_load;

    /*
     * Export functions.
     */

    for (i = 0; i < stp->num_exps; i++) {
	Export* ep = erts_export_put(stp->module, stp->export[i].function,
				     stp->export[i].arity);
	if (!on_load) {
	    ep->address = stp->export[i].address;
	} else {
	    /*
	     * Don't make any of the exported functions
	     * callable yet.
	     */
	    ep->address = ep->code+3;
	    ep->code[4] = (BeamInstr) stp->export[i].address;
	}
    }

    /*
     * Import functions and patch all callers.
     */

    for (i = 0; i < stp->num_imports; i++) {
	Eterm mod;
	Eterm func;
	Uint arity;
	BeamInstr import;
	Uint current;
	Uint next;

	mod = stp->import[i].module;
	func = stp->import[i].function;
	arity = stp->import[i].arity;
	import = (BeamInstr) erts_export_put(mod, func, arity);
	current = stp->import[i].patches;
	while (current != 0) {
	    ASSERT(current < stp->ci);
	    next = stp->code[current];
	    stp->code[current] = import;
	    current = next;
	}
    }

    /*
     * Fix all funs.
     */ 

    if (stp->num_lambdas > 0) {
	for (i = 0; i < stp->num_lambdas; i++) {
	    unsigned entry_label = stp->lambdas[i].label;
	    ErlFunEntry* fe = stp->lambdas[i].fe;
	    BeamInstr* code_ptr = (BeamInstr *) (stp->code + stp->labels[entry_label].value);

	    if (fe->address[0] != 0) {
		/*
		 * We are hiding a pointer into older code.
		 */
		erts_refc_dec(&fe->refc, 1);
	    }
	    fe->address = code_ptr;
#ifdef HIPE
	    hipe_set_closure_stub(fe, stp->lambdas[i].num_free);
#endif
	}
    }
}


static int
transform_engine(LoaderState* st)
{
    Uint op;
    int ap;			/* Current argument. */
    Uint* restart;		/* Where to restart if current match fails. */
    GenOpArg def_vars[TE_MAX_VARS]; /* Default buffer for variables. */
    GenOpArg* var = def_vars;
    int i;			/* General index. */
    Uint mask;
    GenOp* instr;
    Uint* pc;
    int rval;

    ASSERT(gen_opc[st->genop->op].transform != -1);
    pc = op_transform + gen_opc[st->genop->op].transform;
    restart = pc;

 restart:
    if (var != def_vars) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) var);
	var = def_vars;
    }
    ASSERT(restart != NULL);
    pc = restart;
    ASSERT(*pc < NUM_TOPS);	/* Valid instruction? */
    ASSERT(*pc == TOP_try_me_else || *pc == TOP_fail);
    instr = st->genop;

#define RETURN(r) rval = (r); goto do_return;

#ifdef DEBUG
    restart = NULL;
#endif
    ap = 0;
    for (;;) {
	op = *pc++;

	switch (op) {
	case TOP_is_op:
	    if (instr == NULL) {
		/*
		 * We'll need at least one more instruction to decide whether
		 * this combination matches or not.
		 */
		RETURN(TE_SHORT_WINDOW);
	    }
	    if (*pc++ != instr->op)
		goto restart;
	    break;
	case TOP_is_type:
	    mask = *pc++;

	    ASSERT(ap < instr->arity);
	    ASSERT(instr->a[ap].type < BEAM_NUM_TAGS);
	    if (((1 << instr->a[ap].type) & mask) == 0)
		goto restart;
	    break;
	case TOP_pred:
	    i = *pc++;
	    switch (i) {
#define RVAL i
#include "beam_pred_funcs.h"
#undef RVAL
	    default:
		ASSERT(0);
	    }
	    if (i == 0)
		goto restart;
	    break;
	case TOP_is_eq:
	    ASSERT(ap < instr->arity);
	    if (*pc++ != instr->a[ap].val)
		goto restart;
	    break;
	case TOP_is_same_var:
	    ASSERT(ap < instr->arity);
	    i = *pc++;
	    ASSERT(i < TE_MAX_VARS);
	    if (var[i].type != instr->a[ap].type)
		goto restart;
	    switch (var[i].type) {
	    case TAG_r: case TAG_n: break;
	    default:
		if (var[i].val != instr->a[ap].val)
		    goto restart;
	    }
	    break;
#if defined(TOP_is_bif)
	case TOP_is_bif:
	    {
		int bif_number = *pc++;
		
		/*
		 * In debug build, the type must be 'u'.
		 * In a real build, don't match.  (I.e. retain the original
		 * call instruction, this will work, but it will be a
		 * slight performance loss.)
		 */

		ASSERT(instr->a[ap].type == TAG_u);
		if (instr->a[ap].type != TAG_u)
		    goto restart;

		/*
		 * In debug build, the assertion will catch invalid indexes
		 * immediately.  In a real build, the loader will issue
		 * an diagnostic later when the instruction is loaded.
		 */

		i = instr->a[ap].val;
		ASSERT(i < st->num_imports);
		if (i >= st->num_imports || st->import[i].bf == NULL)
		    goto restart;
		if (bif_number != -1 &&
		    bif_export[bif_number]->code[4] != (BeamInstr) st->import[i].bf) {
		    goto restart;
		}
	    }
	    break;

#endif
#if defined(TOP_is_not_bif)
	case TOP_is_not_bif:
	    {
		pc++;
		
		/*
		 * In debug build, the type must be 'u'.
		 */

		ASSERT(instr->a[ap].type == TAG_u);
		if (instr->a[ap].type != TAG_u) {
		    goto restart;
		}
		i = instr->a[ap].val;

		/*
		 * erlang:apply/2,3 are strange. They exist as (dummy) BIFs
		 * so that they are included in the export table before
		 * the erlang module is loaded. They also exist in the erlang
		 * module as functions. When used in code, a special Beam
		 * instruction is used.
		 * 
		 * Below we specially recognize erlang:apply/2,3 as special.
		 * This is necessary because after setting a trace pattern on
		 * them, you cannot no longer see from the export entry that
		 * they are special.
		 */
		if (i < st->num_imports) {
		    if (st->import[i].bf != NULL ||
			(st->import[i].module == am_erlang &&
			 st->import[i].function == am_apply &&
			 (st->import[i].arity == 2 || st->import[i].arity == 3))) {
			goto restart;
		    }
		}
	    }
	    break;

#endif
#if defined(TOP_is_func)
	case TOP_is_func:
	    {
		Eterm mod = *pc++;
		Eterm func = *pc++;
		int arity = *pc++;

		ASSERT(instr->a[ap].type == TAG_u);
		if (instr->a[ap].type != TAG_u) {
		    goto restart;
		}
		i = instr->a[ap].val;
		ASSERT(i < st->num_imports);
		if (i >= st->num_imports || st->import[i].module != mod ||
		    st->import[i].function != func ||
		    (arity < MAX_ARG && st->import[i].arity != arity)) {
		    goto restart;
		}
	    }
	    break;
#endif
	case TOP_set_var_next_arg:
	    ASSERT(ap < instr->arity);
	    i = *pc++;
	    ASSERT(i < TE_MAX_VARS);
	    var[i].type = instr->a[ap].type;
	    var[i].val = instr->a[ap].val;
	    ap++;
	    break;

#if defined(TOP_rest_args)
	case TOP_rest_args:
	    {
		int n = *pc++;
		var = erts_alloc(ERTS_ALC_T_LOADER_TMP,
				 instr->arity * sizeof(GenOpArg));
		for (i = 0; i < n; i++) {
		    var[i] = def_vars[i];
		}
		while (i < instr->arity) {
		    var[i] = instr->a[i];
		    i++;
		}
	    }
	    break;
#endif

	case TOP_next_arg:
	    ap++;
	    break;
	case TOP_next_instr:
	    instr = instr->next;
	    ap = 0;
	    break;
	case TOP_commit:
	    instr = instr->next; /* The next_instr was optimized away. */

	    /*
	     * The left-hand side of this transformation matched.
	     * Delete all matched instructions.
	     */
	    while (st->genop != instr) {
		GenOp* next = st->genop->next;
		FREE_GENOP(st, st->genop);
		st->genop = next;
	    }
#ifdef DEBUG
	    instr = 0;
#endif
	    break;

#if defined(TOP_call)
	case TOP_call:
	    {
		GenOp** lastp;
		GenOp* new_instr;

		i = *pc++;
		switch (i) {
#define RVAL new_instr
#include "beam_tr_funcs.h"
#undef RVAL
		default:
		    new_instr = NULL; /* Silence compiler warning. */
		    ASSERT(0);
		}
		if (new_instr == NULL) {
		    goto restart;
		}

		lastp = &new_instr;
		while (*lastp != NULL) {
		    lastp = &((*lastp)->next);
		}
		 
		instr = instr->next; /* The next_instr was optimized away. */

		/*
		 * The left-hand side of this transformation matched.
		 * Delete all matched instructions.
		 */
		while (st->genop != instr) {
		    GenOp* next = st->genop->next;
		    FREE_GENOP(st, st->genop);
		    st->genop = next;
		}
		*lastp = st->genop;
		st->genop = new_instr;
	    }
	    break;
#endif
	case TOP_new_instr:
	    /*
	     * Note that the instructions are generated in reverse order.
	     */
	    NEW_GENOP(st, instr);
	    instr->next = st->genop;
	    st->genop = instr;
	    ap = 0;
	    break;
	case TOP_store_op:
	    instr->op = *pc++;
	    instr->arity = *pc++;
	    break;
	case TOP_store_type:
	    i = *pc++;
	    instr->a[ap].type = i;
	    instr->a[ap].val = 0;
	    break;
	case TOP_store_val:
	    i = *pc++;
	    instr->a[ap].val = i;
	    break;
	case TOP_store_var:
	    i = *pc++;
	    ASSERT(i < TE_MAX_VARS);
	    instr->a[ap].type = var[i].type;
	    instr->a[ap].val = var[i].val;
	    break;
	case TOP_try_me_else:
	    restart = pc + 1;
	    restart += *pc++;
	    ASSERT(*pc < NUM_TOPS); /* Valid instruction? */
	    break;
	case TOP_end:
	    RETURN(TE_OK);
	case TOP_fail:
	    RETURN(TE_FAIL)
	default:
	    ASSERT(0);
	}
    }
#undef RETURN

 do_return:
    if (var != def_vars) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) var);
    }
    return rval;
}


static void
short_file(int line, LoaderState* stp, unsigned needed)
{
    load_printf(line, stp, "unexpected end of %s when reading %d byte(s)",
		stp->file_name, needed);
}


static void
load_printf(int line, LoaderState* context, char *fmt,...)
{
    erts_dsprintf_buf_t *dsbufp;
    va_list va;

    if (is_non_value(context->module)) {
	/* Suppressed by code:get_chunk/2 */
	return;
    }

    dsbufp = erts_create_logger_dsbuf();

    erts_dsprintf(dsbufp, "%s(%d): Error loading ", __FILE__, line);

    if (is_atom(context->function))
	erts_dsprintf(dsbufp, "function %T:%T/%d", context->module,
		      context->function, context->arity);
    else
	erts_dsprintf(dsbufp, "module %T", context->module);

    if (context->genop)
	erts_dsprintf(dsbufp, ": op %s", gen_opc[context->genop->op].name);

    if (context->specific_op != -1)
	erts_dsprintf(dsbufp, ": %s", opc[context->specific_op].sign);
    else if (context->genop) {
	int i;
	for (i = 0; i < context->genop->arity; i++)
	    erts_dsprintf(dsbufp, " %c",
			  tag_to_letter[context->genop->a[i].type]);
    }

    erts_dsprintf(dsbufp, ":\n  ");

    va_start(va, fmt);
    erts_vdsprintf(dsbufp, fmt, va);
    va_end(va);

    erts_dsprintf(dsbufp, "\n");
#ifdef DEBUG
    erts_fprintf(stderr, "%s", dsbufp->str);
#endif
    erts_send_error_to_logger(context->group_leader, dsbufp);
}


static int
get_int_val(LoaderState* stp, Uint len_code, BeamInstr* result)
{
    Uint count;
    Uint val;

    len_code >>= 5;
    ASSERT(len_code < 8);
    if (len_code == 7) {
	LoadError0(stp, "can't load integers bigger than 8 bytes yet\n");
    }
    count = len_code + 2;
    if (count == 5) {
	Uint msb;
	GetByte(stp, msb);
	if (msb == 0) {
	    count--;
	}
	GetInt(stp, 4, *result);
    } else if (count <= 4) {
	GetInt(stp, count, val);
	*result = ((val << 8*(sizeof(val)-count)) >> 8*(sizeof(val)-count));
    } else {
	LoadError1(stp, "too big integer; %d bytes\n", count);
    }
    return 1;

 load_error:
    return 0;
}


static int
get_erlang_integer(LoaderState* stp, Uint len_code, BeamInstr* result)
{
    Uint count;
    Sint val;
    byte default_buf[128];
    byte* bigbuf = default_buf;
    byte* s;
    int i;
    int neg = 0;
    Uint arity;
    Eterm* hp;

    /*
     * Retrieve the size of the value in bytes.
     */

    len_code >>= 5;
    if (len_code < 7) {
	count = len_code + 2;
    } else {
	Uint tag;
	UWord len_word;

	ASSERT(len_code == 7);
	GetTagAndValue(stp, tag, len_word);
	VerifyTag(stp, TAG_u, tag);
	count = len_word + 9;
    }

    /*
     * Handle values up to the size of an int, meaning either a small or bignum.
     */

    if (count <= sizeof(val)) {
	GetInt(stp, count, val);

	val = ((val << 8*(sizeof(val)-count)) >> 8*(sizeof(val)-count));
	if (IS_SSMALL(val)) {
	    *result = val;
	    return TAG_i;
	} else {
	    *result = new_literal(stp, &hp, BIG_UINT_HEAP_SIZE);
	    (void) small_to_big(val, hp);
	    return TAG_q;
	}
    }

    /*
     * Make sure that the number will fit in our temporary buffer
     * (including margin).
     */

    if (count+8 > sizeof(default_buf)) {
	bigbuf = erts_alloc(ERTS_ALC_T_LOADER_TMP, count+8);
    }

    /*
     * Copy the number reversed to our temporary buffer.
     */

    GetString(stp, s, count);
    for (i = 0; i < count; i++) {
	bigbuf[count-i-1] = *s++;
    }

    /*
     * Check if the number is negative, and negate it if so.
     */

    if ((bigbuf[count-1] & 0x80) != 0) {
	unsigned carry = 1;

	neg = 1;
	for (i = 0; i < count; i++) {
	    bigbuf[i] = ~bigbuf[i] + carry;
	    carry = (bigbuf[i] == 0 && carry == 1);
	}
	ASSERT(carry == 0);
    }

    /*
     * Align to word boundary.
     */

    if (bigbuf[count-1] == 0) {
	count--;
    }
    if (bigbuf[count-1] == 0) {
	LoadError0(stp, "bignum not normalized");
    }
    while (count % sizeof(Eterm) != 0) {
	bigbuf[count++] = 0;
    }

    /*
     * Allocate heap space for the bignum and copy it.
     */

    arity = count/sizeof(Eterm);
    *result = new_literal(stp, &hp, arity+1);
    (void) bytes_to_big(bigbuf, count, neg, hp);

    if (bigbuf != default_buf) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) bigbuf);
    }
    return TAG_q;

 load_error:
    if (bigbuf != default_buf) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) bigbuf);
    }
    return -1;
}

/*
 * Converts an IFF id to a printable string.
 */

static void
id_to_string(Uint id, char* s)
{
    int i;

    for (i = 3; i >= 0; i--) {
	*s++ = (id >> i*8) & 0xff;
    }
    *s++ = '\0';
}

static void
new_genop(LoaderState* stp)
{
    GenOpBlock* p = (GenOpBlock *) erts_alloc(ERTS_ALC_T_LOADER_TMP,
					      sizeof(GenOpBlock));
    int i;

    p->next = stp->genop_blocks;
    stp->genop_blocks = p;
    for (i = 0; i < sizeof(p->genop)/sizeof(p->genop[0])-1; i++) {
	p->genop[i].next = p->genop + i + 1;
    }
    p->genop[i].next = NULL;
    stp->free_genop = p->genop;
}

static int
new_label(LoaderState* stp)
{
    int num = stp->num_labels;

    stp->num_labels++;
    stp->labels = (Label *) erts_realloc(ERTS_ALC_T_LOADER_TMP,
					 (void *) stp->labels,
					 stp->num_labels * sizeof(Label));
    stp->labels[num].value = 0;
    stp->labels[num].patches = 0;
    return num;
}

static void
new_literal_patch(LoaderState* stp, int pos)
{
    LiteralPatch* p = erts_alloc(ERTS_ALC_T_LOADER_TMP, sizeof(LiteralPatch));
    p->pos = pos;
    p->next = stp->literal_patches;
    stp->literal_patches = p;
}

static void
new_string_patch(LoaderState* stp, int pos)
{
    StringPatch* p = erts_alloc(ERTS_ALC_T_LOADER_TMP, sizeof(StringPatch));
    p->pos = pos;
    p->next = stp->string_patches;
    stp->string_patches = p;
}

static Uint
new_literal(LoaderState* stp, Eterm** hpp, Uint heap_size)
{
    Literal* lit;

    if (stp->allocated_literals == 0) {
	Uint need;

	ASSERT(stp->literals == 0);
	ASSERT(stp->num_literals == 0);
	stp->allocated_literals = 8;
	need = stp->allocated_literals * sizeof(Literal);
	stp->literals = (Literal *) erts_alloc(ERTS_ALC_T_LOADER_TMP,
					       need);
    } else if (stp->allocated_literals <= stp->num_literals) {
	Uint need;

	stp->allocated_literals *= 2;
	need = stp->allocated_literals * sizeof(Literal);
	stp->literals = (Literal *) erts_realloc(ERTS_ALC_T_LOADER_TMP,
						 (void *) stp->literals,
						 need);
    }

    stp->total_literal_size += heap_size;
    lit = stp->literals + stp->num_literals;
    lit->offset = 0;
    lit->heap_size = heap_size;
    lit->heap = erts_alloc(ERTS_ALC_T_LOADER_TMP, heap_size*sizeof(Eterm));
    lit->term = make_boxed(lit->heap);
    *hpp = lit->heap;
    return stp->num_literals++;
}

Eterm
erts_module_info_0(Process* p, Eterm module)
{
    Eterm *hp;
    Eterm list = NIL;
    Eterm tup;

    if (is_not_atom(module)) {
	return THE_NON_VALUE;
    }

    if (erts_get_module(module) == NULL) {
	return THE_NON_VALUE;
    }

#define BUILD_INFO(What) \
    tup = erts_module_info_1(p, module, What); \
    hp = HAlloc(p, 5); \
    tup = TUPLE2(hp, What, tup); \
    hp += 3; \
    list = CONS(hp, tup, list)

    BUILD_INFO(am_compile);
    BUILD_INFO(am_attributes);
    BUILD_INFO(am_imports);
    BUILD_INFO(am_exports);
#undef BUILD_INFO
    return list;
}

Eterm
erts_module_info_1(Process* p, Eterm module, Eterm what)
{
    if (what == am_module) {
	return module;
    } else if (what == am_imports) {
	return NIL;
    } else if (what == am_exports) {
	return exported_from_module(p, module);
    } else if (what == am_functions) {
	return functions_in_module(p, module);
    } else if (what == am_attributes) {
	return attributes_for_module(p, module);
    } else if (what == am_compile) {
	return compilation_info_for_module(p, module);
    } else if (what == am_native_addresses) {
	return native_addresses(p, module);
    }
    return THE_NON_VALUE;
}

/*
 * Builds a list of all functions in the given module:
 *     [{Name, Arity},...]
 *
 * Returns a tagged term, or 0 on error.
 */

Eterm
functions_in_module(Process* p, /* Process whose heap to use. */
		     Eterm mod) /* Tagged atom for module. */
{
    Module* modp;
    BeamInstr* code;
    int i;
    Uint num_functions;
    Eterm* hp;
    Eterm result = NIL;

    if (is_not_atom(mod)) {
	return THE_NON_VALUE;
    }

    modp = erts_get_module(mod);
    if (modp == NULL) {
	return THE_NON_VALUE;
    }
    code = modp->code;
    num_functions = code[MI_NUM_FUNCTIONS];
    hp = HAlloc(p, 5*num_functions);
    for (i = num_functions-1; i >= 0 ; i--) {
	BeamInstr* func_info = (BeamInstr *) code[MI_FUNCTIONS+i];
	Eterm name = (Eterm) func_info[3];
	int arity = (int) func_info[4];
	Eterm tuple;

	ASSERT(is_atom(name));
	tuple = TUPLE2(hp, name, make_small(arity));
	hp += 3;
	result = CONS(hp, tuple, result);
	hp += 2;
    }
    return result;
}

/*
 * Builds a list of all functions including native addresses.
 *     [{Name,Arity,NativeAddress},...]
 *
 * Returns a tagged term, or 0 on error.
 */

static Eterm
native_addresses(Process* p, Eterm mod)
{
    Module* modp;
    BeamInstr* code;
    int i;
    Eterm* hp;
    Uint num_functions;
    Uint need;
    Eterm* hp_end;
    Eterm result = NIL;

    if (is_not_atom(mod)) {
	return THE_NON_VALUE;
    }

    modp = erts_get_module(mod);
    if (modp == NULL) {
	return THE_NON_VALUE;
    }

    code = modp->code;
    num_functions = code[MI_NUM_FUNCTIONS];
    need = (6+BIG_UINT_HEAP_SIZE)*num_functions;
    hp = HAlloc(p, need);
    hp_end = hp + need;
    for (i = num_functions-1; i >= 0 ; i--) {
	BeamInstr* func_info = (BeamInstr *) code[MI_FUNCTIONS+i];
	Eterm name = (Eterm) func_info[3];
	int arity = (int) func_info[4];
	Eterm tuple;

	ASSERT(is_atom(name));
	if (func_info[1] != 0) {
	    Eterm addr = erts_bld_uint(&hp, NULL, func_info[1]);
	    tuple = erts_bld_tuple(&hp, NULL, 3, name, make_small(arity), addr);
	    result = erts_bld_cons(&hp, NULL, tuple, result);
	}
    }
    HRelease(p, hp_end, hp);
    return result;
}


/*
 * Builds a list of all exported functions in the given module:
 *     [{Name, Arity},...]
 *
 * Returns a tagged term, or 0 on error.
 */

Eterm
exported_from_module(Process* p, /* Process whose heap to use. */
		     Eterm mod) /* Tagged atom for module. */
{
    int i;
    Eterm* hp = NULL;
    Eterm* hend = NULL;
    Eterm result = NIL;

    if (is_not_atom(mod)) {
	return THE_NON_VALUE;
    }

    for (i = 0; i < export_list_size(); i++) {
	Export* ep = export_list(i);
	
	if (ep->code[0] == mod) {
	    Eterm tuple;
	    
	    if (ep->address == ep->code+3 &&
		ep->code[3] == (BeamInstr) em_call_error_handler) {
		/* There is a call to the function, but it does not exist. */ 
		continue;
	    }

	    if (hp == hend) {
		int need = 10 * 5;
		hp = HAlloc(p, need);
		hend = hp + need;
	    }
	    tuple = TUPLE2(hp, ep->code[1], make_small(ep->code[2]));
	    hp += 3;
	    result = CONS(hp, tuple, result);
	    hp += 2;
	}
    }
    HRelease(p,hend,hp);
    return result;
}


/*
 * Returns a list of all attributes for the module.
 *
 * Returns a tagged term, or 0 on error.
 */

Eterm
attributes_for_module(Process* p, /* Process whose heap to use. */
		      Eterm mod) /* Tagged atom for module. */

{
    Module* modp;
    BeamInstr* code;
    Eterm* hp;
    byte* ext;
    Eterm result = NIL;
    Eterm* end;

    if (is_not_atom(mod) || (is_not_list(result) && is_not_nil(result))) {
	return THE_NON_VALUE;
    }

    modp = erts_get_module(mod);
    if (modp == NULL) {
	return THE_NON_VALUE;
    }
    code = modp->code;
    ext = (byte *) code[MI_ATTR_PTR];
    if (ext != NULL) {
	hp = HAlloc(p, code[MI_ATTR_SIZE_ON_HEAP]);
	end = hp + code[MI_ATTR_SIZE_ON_HEAP];
	result = erts_decode_ext(&hp, &MSO(p), &ext);
	if (is_value(result)) {
	    ASSERT(hp <= end);
	}
        HRelease(p,end,hp);
    }
    return result;
}


/*
 * Returns a list containing compilation information.
 *
 * Returns a tagged term, or 0 on error.
 */

Eterm
compilation_info_for_module(Process* p, /* Process whose heap to use. */
			    Eterm mod) /* Tagged atom for module. */
{
    Module* modp;
    BeamInstr* code;
    Eterm* hp;
    byte* ext;
    Eterm result = NIL;
    Eterm* end;

    if (is_not_atom(mod) || (is_not_list(result) && is_not_nil(result))) {
	return THE_NON_VALUE;
    }

    modp = erts_get_module(mod);
    if (modp == NULL) {
	return THE_NON_VALUE;
    }
    code = modp->code;
    ext = (byte *) code[MI_COMPILE_PTR];
    if (ext != NULL) {
	hp = HAlloc(p, code[MI_COMPILE_SIZE_ON_HEAP]);
	end = hp + code[MI_COMPILE_SIZE_ON_HEAP];
	result = erts_decode_ext(&hp, &MSO(p), &ext);
	if (is_value(result)) {
	    ASSERT(hp <= end);
	}
        HRelease(p,end,hp);
    }
    return result;
}


/*
 * Returns a pointer to {module, function, arity}, or NULL if not found.
 */
BeamInstr *
find_function_from_pc(BeamInstr* pc)
{
    Range* low = modules;
    Range* high = low + num_loaded_modules;
    Range* mid = mid_module;

    while (low < high) {
	if (pc < mid->start) {
	    high = mid;
	} else if (pc > mid->end) {
	    low = mid + 1;
	} else {
	    BeamInstr** low1 = (BeamInstr **) (mid->start + MI_FUNCTIONS);
	    BeamInstr** high1 = low1 + mid->start[MI_NUM_FUNCTIONS];
	    BeamInstr** mid1;

	    while (low1 < high1) {
		mid1 = low1 + (high1-low1) / 2;
		if (pc < mid1[0]) {
		    high1 = mid1;
		} else if (pc < mid1[1]) {
		    mid_module = mid;
		    return mid1[0]+2;
		} else {
		    low1 = mid1 + 1;
		}
	    }
	    return NULL;
	}
	mid = low + (high-low) / 2;
    }
    return NULL;
}

/*
 * Read a specific chunk from a Beam binary.
 */

Eterm
code_get_chunk_2(Process* p, Eterm Bin, Eterm Chunk)
{
    LoaderState state;
    Uint chunk = 0;
    ErlSubBin* sb;
    Uint offset;
    Uint bitoffs;
    Uint bitsize;
    byte* start;
    int i;
    Eterm res;
    Eterm real_bin;
    byte* temp_alloc = NULL;

    if ((start = erts_get_aligned_binary_bytes(Bin, &temp_alloc)) == NULL) {
    error:
	erts_free_aligned_binary_bytes(temp_alloc);
	BIF_ERROR(p, BADARG);
    }
    state.module = THE_NON_VALUE; /* Suppress diagnostiscs */
    state.file_name = "IFF header for Beam file";
    state.file_p = start;
    state.file_left = binary_size(Bin);
    for (i = 0; i < 4; i++) {
	Eterm* chunkp;
	Eterm num;
	if (is_not_list(Chunk)) {
	    goto error;
	}
	chunkp = list_val(Chunk);
	num = CAR(chunkp);
	Chunk = CDR(chunkp);
	if (!is_byte(num)) {
	    goto error;
	}
	chunk = chunk << 8 | unsigned_val(num);
    }
    if (is_not_nil(Chunk)) {
	goto error;
    }
    if (!scan_iff_file(&state, &chunk, 1, 1)) {
	erts_free_aligned_binary_bytes(temp_alloc);
	return am_undefined;
    }
    ERTS_GET_REAL_BIN(Bin, real_bin, offset, bitoffs, bitsize);
    if (bitoffs) {
	res = new_binary(p, state.chunks[0].start, state.chunks[0].size);
    } else {
	sb = (ErlSubBin *) HAlloc(p, ERL_SUB_BIN_SIZE);
	sb->thing_word = HEADER_SUB_BIN;
	sb->orig = real_bin;
	sb->size = state.chunks[0].size;
	sb->bitsize = 0;
	sb->bitoffs = 0;
	sb->offs = offset + (state.chunks[0].start - start);
	sb->is_writable = 0;
	res = make_binary(sb);
    }
    erts_free_aligned_binary_bytes(temp_alloc);
    return res;
}

/*
 * Calculate the MD5 for a module.
 */
  
Eterm
code_module_md5_1(Process* p, Eterm Bin)
{
    LoaderState state;
    byte* temp_alloc = NULL;

    if ((state.file_p = erts_get_aligned_binary_bytes(Bin, &temp_alloc)) == NULL) {
	BIF_ERROR(p, BADARG);
    }
    state.module = THE_NON_VALUE; /* Suppress diagnostiscs */
    state.file_name = "IFF header for Beam file";
    state.file_left = binary_size(Bin);

    if (!scan_iff_file(&state, chunk_types, NUM_CHUNK_TYPES, NUM_MANDATORY)) {
	return am_undefined;
    }
    erts_free_aligned_binary_bytes(temp_alloc);
    return new_binary(p, state.mod_md5, sizeof(state.mod_md5));
}

#define WORDS_PER_FUNCTION 6

static BeamInstr*
make_stub(BeamInstr* fp, Eterm mod, Eterm func, Uint arity, Uint native, BeamInstr OpCode)
{
    fp[0] = (BeamInstr) BeamOp(op_i_func_info_IaaI);
    fp[1] = native;
    fp[2] = mod;
    fp[3] = func;
    fp[4] = arity;
#ifdef HIPE
    if (native) {
	fp[5] = BeamOpCode(op_move_return_nr);
	hipe_mfa_save_orig_beam_op(mod, func, arity, fp+5);
    }
#endif
    fp[5] = OpCode;
    return fp + WORDS_PER_FUNCTION;
}

static byte*
stub_copy_info(LoaderState* stp,
	       int chunk,	/* Chunk: ATTR_CHUNK or COMPILE_CHUNK */
	       byte* info,	/* Where to store info. */
	       BeamInstr* ptr_word,	/* Where to store pointer into info. */
	       BeamInstr* size_word) /* Where to store size of info. */
{
    Sint decoded_size;
    Uint size = stp->chunks[chunk].size;
    if (size != 0) {
	memcpy(info, stp->chunks[chunk].start, size);
	*ptr_word = (BeamInstr) info;
	decoded_size = erts_decode_ext_size(info, size, 0);
	if (decoded_size < 0) {
 	    return 0;
 	}
	*size_word = decoded_size;
    }
    return info + size;
}

static int
stub_read_export_table(LoaderState* stp)
{
    int i;

    GetInt(stp, 4, stp->num_exps);
    if (stp->num_exps > stp->num_functions) {
	LoadError2(stp, "%d functions exported; only %d functions defined",
		   stp->num_exps, stp->num_functions);
    }
    stp->export
	= (ExportEntry *) erts_alloc(ERTS_ALC_T_LOADER_TMP,
				     stp->num_exps * sizeof(ExportEntry));

    for (i = 0; i < stp->num_exps; i++) {
	Uint n;

	GetInt(stp, 4, n);
	GetAtom(stp, n, stp->export[i].function);
	GetInt(stp, 4, n);
	if (n > MAX_REG) {
	    LoadError2(stp, "export table entry %d: absurdly high arity %d", i, n);
	}
	stp->export[i].arity = n;
	GetInt(stp, 4, n);	/* Ignore label */
    }
    return 1;

 load_error:
    return 0;
}

static void
stub_final_touch(LoaderState* stp, BeamInstr* fp)
{
    int i;
    int n = stp->num_exps;
    Eterm function = fp[3];
    int arity = fp[4];
#ifdef HIPE
    Lambda* lp;
#endif

    /*
     * Test if the function should be exported.
     */

    for (i = 0; i < n; i++) {
	if (stp->export[i].function == function && stp->export[i].arity == arity) {
	    Export* ep = erts_export_put(fp[2], function, arity);
	    ep->address = fp+5;
	    return;
	}
    }

    /*
     * Must be a plain local function or a lambda local function.
     * Search the lambda table to find out which.
     */
    
#ifdef HIPE
    n = stp->num_lambdas;
    for (i = 0, lp = stp->lambdas; i < n; i++, lp++) {
        ErlFunEntry* fe = stp->lambdas[i].fe;
	if (lp->function == function && lp->arity == arity) {
	    fp[5] = (Eterm) BeamOpCode(op_hipe_trap_call_closure);
            fe->address = &(fp[5]);
	}
    }
#endif
    return;
}


/* Takes an erlang list of addresses:
   [{Adr, Patchtyppe} | Addresses]
   and the address of a fun_entry.
*/
int 
patch(Eterm Addresses, Uint fe) 
 {
#ifdef HIPE
  Eterm* listp;
  Eterm tuple;
  Eterm* tp;
  Eterm  patchtype;
  Uint AddressToPatch;

  while (!is_nil(Addresses)) {
    listp = list_val(Addresses);

    tuple = CAR(listp);
    if (is_not_tuple(tuple)) {
      return 0; /* Signal error */
    }

    tp = tuple_val(tuple);
    if (tp[0] != make_arityval(2)) {
      return 0; /* Signal error */
    }
    
    if(term_to_Uint(tp[1], &AddressToPatch) == 0) {
      return 0; /* Signal error */
    }

    patchtype = tp[2];    
    if (is_not_atom(patchtype)) {
      return 0; /* Signal error */
    }
    
    hipe_patch_address((Uint *)AddressToPatch, patchtype, fe);

    Addresses = CDR(listp);


  }

#endif
  return 1;
}


int
patch_funentries(Eterm Patchlist) 
 {
#ifdef HIPE   
  while (!is_nil(Patchlist)) {
    Eterm Info;
    Eterm MFA;
    Eterm Addresses;
    Eterm tuple;
    Eterm Mod;
    Eterm* listp;
    Eterm* tp;
    ErlFunEntry* fe;
    Uint index;
    Uint uniq;
    Uint native_address;
     
    listp = list_val(Patchlist);
    tuple = CAR(listp);
    Patchlist = CDR(listp);

    if (is_not_tuple(tuple)) {
      return 0; /* Signal error */
    }

    tp = tuple_val(tuple);
    if (tp[0] != make_arityval(3)) {
      return 0; /* Signal error */
    }
    
    Info = tp[1];
    if (is_not_tuple(Info)) {
      return 0; /* Signal error */
    }
    Addresses = tp[2];    
     if (is_not_list(Addresses)) {
       return 0; /* Signal error */
    }
    
    if(term_to_Uint(tp[3], &native_address) == 0) {
      return 0; /* Signal error */
    }



    tp = tuple_val(Info);
    if (tp[0] != make_arityval(3)) {
      return 0; /* Signal error */
    }
    MFA = tp[1];
    if (is_not_tuple(MFA)) {
      return 0; /* Signal error */
    }
    if(term_to_Uint(tp[2], &uniq) == 0){
      return 0; /* Signal error */
    }
    if(term_to_Uint(tp[3], &index) == 0) {
      return 0; /* Signal error */
    }




    tp = tuple_val(MFA);
    if (tp[0] != make_arityval(3)) {
      return 0; /* Signal error */
     }
    Mod = tp[1];
    if (is_not_atom(Mod)) {
      return 0; /* Signal error */
    }
      
  

    fe = erts_get_fun_entry(Mod, uniq, index);
    fe->native_address = (Uint *)native_address;
    erts_refc_dec(&fe->refc, 1);

    if (!patch(Addresses, (Uint) fe))
      return 0;

  }
#endif
  return 1; /* Signal that all went well */
}


/*
 * Do a dummy load of a module. No threaded code will be loaded.
 * Used for loading native code.
 * Will also patch all references to fun_entries to point to 
 * the new fun_entries created.
 */

Eterm
erts_make_stub_module(Process* p, Eterm Mod, Eterm Beam, Eterm Info)
{
    LoaderState state;
    BeamInstr Funcs;
    BeamInstr Patchlist;
    Eterm* tp;
    BeamInstr* code = NULL;
    BeamInstr* ptrs;
    BeamInstr* fp;
    byte* info;
    Uint ci;
    int n;
    int code_size;
    int rval;
    int i;
    ErlDrvBinary* bin = NULL;
    byte* temp_alloc = NULL;
    byte* bytes;
    Uint size;

    /*
     * Must initialize state.lambdas here because the error handling code
     * at label 'error' uses it.
     */
    init_state(&state);

    if (is_not_atom(Mod)) {
	goto error;
    }
    if (is_not_tuple(Info)) {
	goto error;
    }
    tp = tuple_val(Info);
    if (tp[0] != make_arityval(2)) {
      goto error;
    }
    Funcs = tp[1];
    Patchlist = tp[2];        
   
    if ((n = list_length(Funcs)) < 0) {
	goto error;
    }
    if ((bytes = erts_get_aligned_binary_bytes(Beam, &temp_alloc)) == NULL) {
	goto error;
    }
    size = binary_size(Beam);

    /*
     * Uncompressed if needed.
     */
    if (!(size >= 4 && bytes[0] == 'F' && bytes[1] == 'O' &&
	  bytes[2] == 'R' && bytes[3] == '1')) {
	bin = (ErlDrvBinary *) erts_gzinflate_buffer((char*)bytes, size);
	if (bin == NULL) {
	    goto error;
	}
	bytes = (byte*)bin->orig_bytes;
	size = bin->orig_size;
    }
    
    /*
     * Scan the Beam binary and read the interesting sections.
     */

    state.file_name = "IFF header for Beam file";
    state.file_p = bytes;
    state.file_left = size;
    state.module = Mod;
    state.group_leader = p->group_leader;
    state.num_functions = n;
    if (!scan_iff_file(&state, chunk_types, NUM_CHUNK_TYPES, NUM_MANDATORY)) {
	goto error;
    }
    define_file(&state, "code chunk header", CODE_CHUNK);
    if (!read_code_header(&state)) {
	goto error;
    }
    define_file(&state, "atom table", ATOM_CHUNK);
    if (!load_atom_table(&state)) {
	goto error;
    }
    define_file(&state, "export table", EXP_CHUNK);
    if (!stub_read_export_table(&state)) {
	goto error;
    }
    
    if (state.chunks[LAMBDA_CHUNK].size > 0) {
	define_file(&state, "lambda (fun) table", LAMBDA_CHUNK);
	if (!read_lambda_table(&state)) {
	    goto error;
	}
    }

    /*
     * Allocate memory for the stub module.
     */

    code_size = ((WORDS_PER_FUNCTION+1)*n + MI_FUNCTIONS + 2) * sizeof(BeamInstr);
    code_size += state.chunks[ATTR_CHUNK].size;
    code_size += state.chunks[COMPILE_CHUNK].size;
    code = erts_alloc_fnf(ERTS_ALC_T_CODE, code_size);
    if (!code) {
	goto error;
    }

    /*
     * Initialize code area.
     */

    code[MI_NUM_FUNCTIONS] = n;
    code[MI_ATTR_PTR] = 0;
    code[MI_ATTR_SIZE] = 0;
    code[MI_ATTR_SIZE_ON_HEAP] = 0;
    code[MI_COMPILE_PTR] = 0;
    code[MI_COMPILE_SIZE] = 0;
    code[MI_COMPILE_SIZE_ON_HEAP] = 0;
    code[MI_NUM_BREAKPOINTS] = 0;
    code[MI_ON_LOAD_FUNCTION_PTR] = 0;
    ci = MI_FUNCTIONS + n + 1;

    /*
     * Make stubs for all functions.
     */

    ptrs = code + MI_FUNCTIONS;
    fp = code + ci;
    for (i = 0; i < n; i++) {
	Eterm* listp;
	Eterm tuple;
	Eterm* tp;
	Eterm func;
	Eterm arity_term;
	Uint arity;
	Uint native_address;
	Eterm op;

	if (is_nil(Funcs)) {
	    break;
	}
	listp = list_val(Funcs);
	tuple = CAR(listp);
	Funcs = CDR(listp);

	/* Error checking */
	if (is_not_tuple(tuple)) {
	    goto error;
	}
	tp = tuple_val(tuple);
	if (tp[0] != make_arityval(3)) {
	    goto error;
	}
	func = tp[1];
	arity_term = tp[2];
	if (is_not_atom(func) || is_not_small(arity_term)) {
	    goto error;
	}
	arity = signed_val(arity_term);
	if (arity < 0) {
	    goto error;
	}
	if (term_to_Uint(tp[3], &native_address) == 0) {
	    goto error;
	}

	/*
	 * Set the pointer and make the stub. Put a return instruction
	 * as the body until we know what kind of trap we should put there.
	 */
	ptrs[i] = (BeamInstr) fp;
#ifdef HIPE
	op = (Eterm) BeamOpCode(op_hipe_trap_call); /* Might be changed later. */
#else
	op = (Eterm) BeamOpCode(op_move_return_nr);
#endif
	fp = make_stub(fp, Mod, func, arity, (Uint)native_address, op);
    }

    /*
     * Insert the last pointer and the int_code_end instruction.
     */

    ptrs[i] = (BeamInstr) fp;
    *fp++ = (BeamInstr) BeamOp(op_int_code_end);

    /*
     * Copy attributes and compilation information.
     */

    info = (byte *) fp;
    info = stub_copy_info(&state, ATTR_CHUNK, info,
			  code+MI_ATTR_PTR, code+MI_ATTR_SIZE_ON_HEAP);
    if (info == NULL) {
	goto error;
    }
    info = stub_copy_info(&state, COMPILE_CHUNK, info,
			  code+MI_COMPILE_PTR, code+MI_COMPILE_SIZE_ON_HEAP);
    if (info == NULL) {
	goto error;
    }

    /*
     * Insert the module in the module table.
     */

    rval = insert_new_code(p, 0, p->group_leader, Mod, code, code_size,
			   BEAM_CATCHES_NIL);
    if (rval < 0) {
	goto error;
    }

    /*
     * Export all stub functions and insert the correct type of HiPE trap.
     */

    fp = code + ci;
    for (i = 0; i < n; i++) {
	stub_final_touch(&state, fp);
	fp += WORDS_PER_FUNCTION;
    }

    if (patch_funentries(Patchlist)) {
	erts_free_aligned_binary_bytes(temp_alloc);
	if (state.lambdas != state.def_lambdas) {
	    erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.lambdas);
	}
	if (bin != NULL) {
	    driver_free_binary(bin);
	}
	return Mod;
    }

 error:
    erts_free_aligned_binary_bytes(temp_alloc);
    if (code != NULL) {
	erts_free(ERTS_ALC_T_CODE, code);
    }
    if (state.lambdas != state.def_lambdas) {
	erts_free(ERTS_ALC_T_LOADER_TMP, (void *) state.lambdas);
    }
    if (bin != NULL) {
	driver_free_binary(bin);
    }

	
    BIF_ERROR(p, BADARG);
}

#undef WORDS_PER_FUNCTION

static int safe_mul(UWord a, UWord b, UWord* resp)
{
    Uint res = a * b; /* XXX:Pan - used in bit syntax, the multiplication has to be stored in Uint */
    *resp = res;

    if (b == 0) {
	return 1;
    } else {
	return (res / b) == a;
    }
}